A variety of accessories may be fitted to most diving regulators, some of which are considered standard equipment. Many of them are attached to a port on the first stage. Two types of port are provided – high pressure ports for pressure measurement, with a 7/16" UNF thread and O-ring seal, and low-pressure ports to supply gas to the accessory, which are usually 3/8" UNF with O-ring seal, but a few models used 1/2" UNF for the primary regulator. When not used these ports are sealed by screw-in plugs.
Anti-freezing modification As gas leaves the cylinder it decreases in pressure in the first stage, becoming very cold due to
adiabatic expansion. Where the ambient water temperature is less than 5 °C any water in contact with the regulator may freeze. If this ice jams the diaphragm or piston spring, preventing the valve closing, a free-flow may ensue that can empty a full cylinder within a minute or two, and the free-flow causes further cooling in a positive feedback loop. Generally the water that freezes is in the ambient pressure chamber around a spring that keeps the valve open and not moisture in the breathing gas from the cylinder, but that is also possible if the air is not adequately filtered. The modern trend of using plastics to replace metal components in regulators encourages freezing because it insulates the inside of a cold regulator from the warmer surrounding water. Some regulators are provided with heat exchange fins in areas where cooling due to air expansion is a problem, such as around the second stage valve seat on some regulators. Cold water kits can be used to reduce the risk of freezing inside the regulator. Some regulators come with this as standard, and some others can be retrofitted. Environmental sealing of the diaphragm main spring chamber using a soft secondary diaphragm and hydrostatic transmitter or a silicone, alcohol or glycol/water mixture
antifreeze liquid in the sealed spring compartment can be used for a diaphragm regulator.
Silicone grease in the spring chamber can be used on a piston first stage. The Poseidon Xstream first stage insulates the external spring and spring housing from the rest of the regulator, so that it is less chilled by the expanding air, and provides large slots in the housing so that the spring can be warmed by the water, thus avoiding the problem of freezing up the external spring. Kirby Morgan have developed a stainless steel tube heat exchanger ("Thermo Exchanger") to warm the gas from the first stage regulator to reduce the risk of second stage scuba regulator freeze when diving in extremely cold water at temperatures down to . The length and relatively good thermal conductivity of the tubing, and the
thermal mass of the block allows sufficient heat from the water to warm the air to within one to two degrees of the surrounding water.
Shut-off valve Some divers install a sliding sleeve type shut-off valve between the low-pressure hose and the demand valve, so they can shut off the flow to a free-flowing second stage, usually when it ices up. This prevents the pressure relief function of the second stage, so a pressure relief valve must be fitted to the first stage to prevent the hose from bursting as pressure increases. Interstage pressure can rise to cylinder pressure if the first stage does not seal.
Pressure relief valve A downstream demand valve serves as a
fail safe for over-pressurization: if a first stage with a demand valve malfunctions and jams in the open position, the demand valve will be over-pressurized and will "free flow". Although it presents the diver with an imminent "out of air" crisis, this failure mode lets gas escape directly into the water without inflating buoyancy devices. The effect of unintentional inflation might be to carry the diver quickly to the surface causing the various
injuries that can result from an over-fast ascent. There are circumstances where regulators are connected to inflatable equipment such as a
rebreather's breathing bag, a
buoyancy compensator, or a
drysuit, but without the need for demand valves. Examples of this are
argon suit inflation sets and "off board" or secondary diluent cylinders for closed-circuit
rebreathers. When no demand valve is connected to a regulator, it should be equipped with a pressure relief valve, unless it has a built in over pressure valve, so that over-pressurization does not inflate any buoyancy devices connected to the regulator or burst the low-pressure hose.
Pressure monitoring A scuba regulator first stage has one or two high pressure ports upstream of all pressure-reducing valves to monitor the gas pressure remaining in the
diving cylinder, provided that the valve is open. The standard connection is an O-ring sealed 7/16" UNF inside thread. There are several types of pressure gauge.
Standard submersible pressure gauge The standard arrangement has a high pressure hose leading to a submersible pressure gauge (SPG) (also called a contents gauge). This is an
analog mechanical gauge, usually with a
Bourdon tube mechanism. It displays with a pointer moving over a dial, usually about diameter. Sometimes they are mounted in a console, which is a plastic or rubber case that holds the breathing gas pressure gauge and other instruments such as a
depth gauge,
dive computer and/or
compass. The high pressure port usually has 7/16"-20 tpi UNF internal thread with an O-ring seal. This makes it impossible to connect a low pressure hose to the high pressure port. Early regulators occasionally used other thread sizes, including 3/8" UNF and 1/8" BSP (Poseidon Cyklon 200), and some of these allowed connection of low-pressure hose to high pressure port, which is dangerous with an upstream valve second stage or a BC or dry suit inflation hose, as the hose could burst under pressure. The first commercially available SPGs were on the US market by the early 1960s. The Sortsways "Sea Vue" pressurge gauge was advertised in 1961. They were initially mounted axially on the HP hose, and later a swivel was added for convenience. Similar gauges had been available on some firefighting SCBA sets earlier (1945?).
High pressure hose The high pressure hose is a small bore flexible hose with permanently swaged end fittings that connects the submersible pressure gauge to the HP port of the regulator first stage. The HP hose end that fits the HP port usually has a very small bore orifice to restrict flow. This both reduces shock loads on the pressure gauge when the cylinder valve is opened, and reduces the loss of gas through the hose if it bursts or leaks for any reason. This tiny hole is vulnerable to blocking by corrosion products if the regulator is flooded, or by dust particles or corrosion products from a contaminated cylinder. At the other end of the hose the fitting to connect to the SPG usually has a swivel, allowing the gauge to be rotated on the hose under pressure. The seal between hose and gauge uses a small component generally referred to as a spool, which seals with an O-ring at each end that fits into the hose end and gauge with a barrel seal. This swivel can leak if the O-rings deteriorate, which is quite common, particularly with oxygen-rich breathing gas. The failure is seldom catastrophic, but the leak will get worse over time. High pressure hose lengths vary from about for sling and side-mount cylinders to about for back mounted scuba. Other lengths may be available off the shelf or made to order for special applications such as rebreathers or back mount with valve down.
Button gauges These are coin-sized analog pressure gauges directly mounted to a high-pressure port on the first stage. They are compact, have no dangling hoses, and few points of failure. They are generally not used on back mounted cylinders because the diver cannot see them there when underwater. They are sometimes used on
side slung stage cylinders. Due to their small size, it can be difficult to read the gauge to a resolution of less than . As they are rigidly mounted to the first stage there is no flexibility in the connection, and they may be vulnerable to impact damage.
Air integrated computers Some
dive computers are designed to measure, display, and monitor pressure in the
diving cylinder. This can be very beneficial to the diver, but if the
dive computer fails the diver can no longer monitor his or her gas reserves. Most divers using a gas-integrated computer will also have a standard air pressure gauge, though, the SPG and hose have several potential points of failure. The computer is either connected to the first stage by a high pressure hose, or has two parts - the pressure transducer on the first stage and the display at the wrist or console, which communicate by wireless data transmission link; the signals are encoded to eliminate the risk of one diver's computer picking up a signal from another diver's transducer or radio interference from other sources. Some dive computers can receive a signal from more than one remote pressure transducer. The Ratio iX3M Tech and others can process and display pressures from up to 10 transmitters.
Handedness Almost all single hose demand regulators are designed to be used with the hose approaching the mouth from the right hand side. In this orientation the exhaust ports are at the lowest point and drainage is effective. There are a few models, notably those made by
Poseidon Diving Systems AB, but historically also from other manufacturers, which have side exhausts and work equally well in either orientation. In effect they have no functional top or bottom. They are more sensitive to lateral tilt, which can affect drainage, but is seldom a problem in practice. A few earlier models were left handed, and at least one Apeks model can be modified for left handed use by rebuilding using the original components. The Mares Loop 15x is unique in having the low pressure hose enter the second stage from the bottom, which allows it to be used with the hose routed under either arm.
Secondary demand valve (Octopus) As a nearly universal standard practice in modern recreational diving, the typical single-hose regulator has a second demand valve fitted for emergency use, mainly for the diver's
buddy, typically referred to as the octopus because of the extra hose, or secondary demand valve. The origins of the secondary demand valve are obscure, and it may have been independently invented several times, but it was used by
Dave Woodward at
UNEXSO around 1965–6 to support the
freedive attempts of
Jacques Mayol. Woodward believed that having the safety divers carry two second stages would be a safer and more practical approach than buddy breathing in the event of an emergency. The secondary demand valve can be a hybrid of a demand valve and a
buoyancy compensator inflation valve. Both types may be called alternate air sources. When the secondary demand valve is integrated with the buoyancy compensator inflation valve, since the inflation valve hose is short (usually just long enough to reach mid-chest), in the event of a diver running out of air, the diver with air remaining would give their primary second stage to the out-of-air diver, and switch to their own integrated inflation valve. A demand valve on a regulator connected to a separate independent
diving cylinder can also be called an alternate air source, and is also a fully redundant air source, as it is totally independent of the primary air source, which has safety advantages.
Configuration The low pressure hose on the secondary demand valve is usually longer than the low pressure hose on the primary DV that the diver uses, and the secondary DV and/or its hose may be colored yellow to aid in locating it in an emergency. The secondary regulator should be clipped to the diver's harness in a position where it can be easily seen and reached by both the diver and the potential sharer of air, with a breakaway connection. The longer hose is used for convenience when sharing air, so that the divers are not forced to stay in an awkward position relative to each other. Technical divers frequently extend this feature and use a 5-foot or 7-foot (1.5 m or 2 m) hose, which allows divers to swim in single file while sharing air, which may be necessary in restricted spaces inside wrecks or caves. In the most common recreational configuration, divers wear the secondary demand valve on the right side, ready for rapid deployment if the buddy runs out of breathing gas. According to an article on the Divers Alert website, the arrangement was originally for the secondary DV to be worn and be deployed on the left side, which allows a standard right handed DV to be used by the recipient without a reverse bend in the hose, which takes maximum advantage of hose length. There is little reliable documentation on whether this was the case, and if so, why it was changed. A comparison of the left and right mountings with reference to the primary function as an emergency gas supply shows some ergonomic advantages the left mount option. These comparisons do not apply with the long hose and necklace or with BCD inflator integrated systems, or with DVs with side exhaust which work upside down. Advantages claimed for the left side mounting are: It is easier to hand off to another diver, using the left hand, and leaving the right hand free, it does not put an additional bend in the hose, which makes better use of the available length, and gives a smooth unstressed lead for face to face sharing and receiver to the left parallel positioning. Face to face positioning allows eye contact, which is useful during ascent, and side by side is useful if the return requires horizontal travel. The purge button is more accessible to the rescuer, as it is on the thumb side of the donating hand. Disadvantages are that it is an awkward arrangement if the diver needs to use it themself, as the hose then needs to be routed round the back of the head, or it may develop a tight bend putting stress on the jaw. It may also lead to confusion if the receiver has only been exposed to right handed donation.
Mouthpiece twin-hose diving regulator made in the 1980s. Its mouthpiece is fitted with a neck strap. The mouthpiece is a part that the user grips in the mouth to make a watertight seal. It is a short flattened-oval tube that goes in between the
lips, with a curved flange that fits between the lips and the teeth and
gums, and seals against the inner surface of the lips. On the inner ends of the flange there are two tabs with enlarged ends, which are gripped between the teeth. These tabs also keep the teeth apart sufficiently to allow comfortable breathing through the gap. Most
recreational diving regulators are fitted with a mouthpiece. In twin-hose regulators and rebreathers, "mouthpiece" may refer to the whole assembly between the two flexible tubes. A mouthpiece prevents clear speech, so a full-face mask is preferred where voice communication is needed. In a few models of scuba regulator the mouthpiece also has an outer rubber flange that fits outside the lips and extends into two straps that fasten together behind the neck. This helps to keep the mouthpiece in place if the user's jaws go slack through unconsciousness or distraction. The mouthpiece safety flange may also be a separate component. The attached neck strap also allows the diver to keep the regulator hanging under the chin where it is protected and ready for use. Recent mouthpieces do not usually include an external flange, but the practice of using a neck strap has been revived by technical divers who use a bungee or surgical rubber "necklace" which can come off the mouthpiece without damage if pulled firmly. The original mouthpieces were usually made from natural rubber and could cause an allergic reaction in some divers. This has been overcome by the use of hypo-allergenic synthetic elastomers such as silicone rubbers.
Swivel hose adaptors Adaptors are available to modify the lead of the low pressure hose where it attaches to the demand valve. There are adaptors which provide a fixed angle and those which are variable while in use. Other swivel adaptors are made to be fitted between the low pressure hose and low pressure port on the first stage to provide hose leads otherwise not possible for the specific regulator. As with all additional moving parts, they are an additional possible point of failure, so should only be used where there is sufficient advantage to offset this risk. They are mainly useful to improve the hose lead on regulators used with
sidemount and
sling mounted cylinders.
Full-face mask or helmet This is stretching the concept of accessory a bit, as it would be equally valid to call the regulator an accessory of the full face mask or helmet, but the two items are closely connected and generally found in use together. Most full face masks and probably most diving helmets currently in use are open circuit demand systems, using a demand valve (in some cases more than one) and supplied from a scuba regulator or a surface supply umbilical from a surface supply panel using a surface supply regulator to control the pressure of primary and reserve air or other breathing gas. Lightweight demand diving helmets are almost always surface supplied, but full face masks are used equally appropriately with scuba open circuit, scuba closed circuit (rebreathers), and surface supplied open circuit. The demand valve is usually firmly attached to the helmet or mask, but there are a few models of full face mask that have removable demand valves with quick connections allowing them to be exchanged under water. These include the
Dräger Panorama and
Kirby-Morgan 48 Supermask.
Positive pressure For some applications it is desirable for the gas inside the mask or helmet to remain at a pressure slightly above ambient at all times while in the water, as this will prevent any contamination from leaking into the gas space during inhalation if the face or neck seal, or the exhaust valve system, does not seal perfectly. In clean water such a leak is a minor problem, but leaks of contaminated water can be a hazard to health, and even life-threatening. A positive pressure inside a free-flow helmet is easily achieved by slightly increasing the opening pressure of the exhaust valve, provided it is adjustable, but for a demand system the cracking pressure of the demand valve must also be adjusted, so that it delivers gas before the internal pressure drops below external ambient pressure. This is not difficult, as a slight adjustment to second stage valve spring pressure is all that is required. The problem is that when the mask or helmet is off the diver, and the gas supply is pressurised, the demand valve will leak continuously, and a large amount of gas can be lost. The
Interspiro Divator Mk II mask has a second stage regulator which has a manual lock on the demand valve to prevent free-flow when the mask is not in use, which unlocks when a breath is taken, and must be reset when the mask is taken off.
Buoyancy compensator and dry suit inflation hoses inflation hose with CEJN 221 connector (right) used for some dry suits Hoses may be fitted to low pressure ports of the regulator first stage to provide gas for inflating buoyancy compensators and/or dry suits. These hoses usually have a quick-connector end with an automatically sealing valve which blocks flow if the hose is disconnected from the buoyancy compensator or suit. There are two basic styles of connector, which are not compatible with each other. The high flow rate CEJN 221 fitting has a larger bore and allows gas flow at a fast enough rate for use as a connector to a demand valve. This is sometimes seen in a combination BC inflator/deflator mechanism with integrated secondary DV (octopus), such as in the AIR II unit from Scubapro. The low flow rate Seatec connector is more common and is the industry standard for BC inflator connectors, and is also popular on dry suits, as the limited flow rate reduces the risk of a blow-up if the valve sticks open. The high flow rate connector is used by some manufacturers on dry suits. Various minor accessories are available to fit these hose connectors. These include interstage pressure gauges, which are used to troubleshoot and tune the regulator (not for use underwater), noisemakers, used to attract attention underwater and on the surface, and valves for inflating tires and inflatable boat floats, making the air in a scuba cylinder available for other purposes.
Instrument consoles Also called combo consoles, these are usually hard rubber or tough plastic moldings which enclose the submersible pressure gauge and have mounting sockets for other diver instrumentation, such as decompression computers, underwater compass, timer and/or depth gauge and occasionally a small plastic slate on which notes can be written either before or during the dive. These instruments would otherwise be carried somewhere else such as strapped to the wrist or forearm or in a pocket and are only regulator accessories for convenience of transport and access, and at greater risk of damage during handling.
Automatic closure device The auto-closure device (ACD) is a mechanism for closing off the inlet opening of a regulator first stage when it is disconnected from a cylinder. A spring-loaded plunger in the inlet is mechanically depressed by contact with the cylinder valve when the regulator is fitted to the cylinder, which opens the port through which air flows into the regulator. In the normally closed condition when not mounted, this valve prevents ingress of water and other contaminants to the first stage interior which could be caused by negligent handling of the equipment or by accident. This is claimed by the manufacturer to extend the service life of the regulator and reduce risk of failure due to internal contamination. However, it is possible for an incorrectly installed ACD to shut off gas supply from a cylinder still containing gas during a dive, and water or other contaminants held in the cylinder valve outlet will not be prevented from entering the first stage.
Breathing gas heating Surface supplied divers operating for long periods in cold water, or using helium based breathing gas mixtures, commonly use a
hot-water suit to maintain body temperature. Part of the water used to heat the suit can be routed through a
water jacket (shroud) around part of the breathing gas supply tubing on the helmet, typically the metal tube between the
bailout valve block and the demand valve inlet. This heats the gas just before delivery through the demand valve, and as a large part of
body heat loss is in heating the inspired air to body temperature on every breath, which is proportional to breathing rate and gas density, this can reduce heat loss significantly on deep dives in cold water. ==Gas compatibility==