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Full-face diving mask
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Full-face diving mask
The AGA Divator full-face diving mask is used by military and civilian divers
Other namesFull face diving mask
Full face mask
Band-mask
UsesProvision of breathing gas, underwater vision, and sometimes communications for underwater divers
InventorYves le Prieur
Related itemsDiving helmet, Diving regulator, Diver communications, Diving mask

A diver in a pool wearing an AGA full face mask
A diver wearing an Ocean Reef full face mask
Head protection helmet for use with Ocean Reef full face diving mask

A full-face diving mask is a type of diving mask that seals the whole of the diver's face from the water and contains a mouthpiece, demand valve or constant flow gas supply that provides the diver with breathing gas.[1] The full face mask has several functions: it lets the diver see clearly underwater, it provides the diver's face with some protection from cold and polluted water and from stings, such as from jellyfish or coral. It increases breathing security and provides a space for equipment that lets the diver communicate with the surface support team.[2]

Full-face masks can be more secure than breathing from an independent mouthpiece; if the diver becomes unconscious or suffers an oxygen toxicity convulsion, the diver can continue to breathe from the mask, unlike a scuba mouthpiece which is normally gripped between the teeth.[1][2]

Full-face diving masks are often used in professional diving. They are relatively rarely used in recreational diving.[2]

Function

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The full-face mask provides breathing gas to the diver, and an air space to facilitate underwater vision. There is usually one air space for both breathing and vision, and this is automatically equalised by the breathing gas during descent. However, some models have a mouthpiece isolating the breathing gas supply from the rest of the interior of the mask, or have a divided interior, and the main air space must then be equalised during descent by exhaling through the nose.[2]

Most full-face masks have an open circuit demand gas supply, but free-flow and closed circuit applications also exist and models used in commercial diving may be normally demand supplied, but with a free-flow option selectable by the diver.[3][4]

Positive pressure

[edit]
See also: Diving regulator § 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.[5][6]

Construction

[edit]
See also: Human factors in diving equipment design § Masks and helmets
The older Royal Navy Clearance Diver's and British SBS frogman's Admiralty Pattern full-face mask with a big front window and a mouthpiece inside made by Siebe Gorman

A full-face mask consists of a transparent faceplate (lenses, or window) through which the diver can see, a connection to a source of breathing gas, a means of removing any water which may get inside, some facility for the diver to block the nose to equalise the ears, a means of sealing these components to the diver's face and preventing ingress of water and a means of securing the assembly to the diver's head. Additional components may include communications equipment, lights, alternative breathing gas connections, and a means to defog the interior surface of the faceplate.[2]

Two basic configurations are in common use: Those with a soft elastomer skirt which seals around the periphery of the face, and those with a rigid frame supporting the other components, which is sealed to the face by a soft foam ring which is clamped to the frame by a metal band, to which the straps are secured (band mask)[citation needed]

Faceplate or lenses

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See also: Underwater vision

The faceplate, viewport, or lens is a transparent window, usually flat, which encloses an air space in front of the diver's eyes and allows the eyes to focus correctly underwater. Several shapes have been used for faceplates and lenses:

  • Circular, as in WWII Italian frogman's rebreathers and in some early British frogman's rebreathers.
  • Oval, in some early British frogman's rebreathers.
  • Triangular with rounded corners, in some Siebe Gorman fullface masks intended for use with an aqualung set, and in the "Jack Browne" band masks made by DESCO for rebreather, open circuit demand, and free-flow applications.[7]
  • Some of DESCO's fullface mask windows were egg-shaped (wider above).
  • Rectangular with the ends of the sides bent back for better sideways visibility, as in the Admiralty Pattern full-face mask made by Siebe Gorman and used on the Siebe Gorman CDBA.
  • In some older masks, small separate lenses, like some gasmasks.
  • Kidney shaped, as in the Cressi full-face mask, or approximately rectangular, with a deep cut-out for the nose pocket, as in the KM-48.

The shape and maximum size of mask and helmet viewports changed with availability of tougher and easily moulded transparent synthetic materials: Clear acrylic (perspex) became available in 1933 and polycarbonate in 1958. Diving helmet windows had been of glass for a long time, but a rigid helmet supported by the corselet resting on the shoulders can carry glass much thicker, stronger, and heavier than a mask strapped over the face and supported by the neck.[citation needed]

Frame

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A structural component is needed to connect all the working parts together and hold the mask in shape. Most full-face masks use a rigid frame for this purpose, which directly or indirectly connects the components together and holds the assembly in shape (Kirby Morgan Exo, Supermask and bandmasks, John Browne mask). The rubber moulding which incorporates the skirt seal may also be sufficiently stiff in places to partially perform this function (Cressi-sub, Scubapro), and the faceplate may also be structural (Dräger Panorama, Ocean Reef Neptune, Aga Divator).

Face seal

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The frame supporting the functional components must be sealed around the face to maintain a leak free internal air space over the eyes, nose, and mouth. Two methods are used.

Soft skirt

[edit]

The soft skirted full-face mask is the more common arrangement, and is generally considerably lighter and more compact than the more sturdy and rigid band masks. There is usually a plastic frame which supports the faceplate (or lenses) and a demand valve, but in some cases the lenses and demand valve or rebreather mouthpiece may be attached independently to the rubber mask structure, which is integral with the skirt.[2]

Band-masks

[edit]
Surface supplied diver wearing a band-mask

A band-mask is a type of full-face diving mask with a rigid and relatively heavy frame, to which a face seal is clamped by a metal band. Band-masks generally have a single faceplate, which may be relatively large, firmly mounted to a rigid frame which also holds the demand valve or other gas supply components. The frame may be of metal (often brass), a strong engineering plastic, or a fibre reinforced resin composite. A face seal, and in some cases a neoprene hood, is clamped onto the edge of the frame by the metal band which gives the mask configuration its name. The band may have several protruding buttons, onto which the straps of the rubber mask harness called the "spider" are fastened to secure the mask to the diver's head. Where a hood is included, it may have a zipper up the back for ease of fitting, and the spider is secured over the hood. A band mask is generally heavier and more cumbersome to fit than a soft skirted full-face mask, but it provides greater security and protection to the diver, and is lighter and quicker to fit than a helmet, though less secure. Most band-masks are fitted with demand systems for gas supply, but can be operated in free-flow mode.[8]

Straps

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A system of three to five straps is used to secure the mask to the diver's head. This component is often referred to as the spider. It is usually a rubber component comprising a group of straps radiating from a central patch or ring, which rests against the back of the diver's head, low enough to resist slipping off over the top. The straps may pass through quick-adjust buckles attached to the mask skirt, or may have holes to hook onto the buttons of a band mask. This strap system is more secure than a single double-ended half-mask strap, however, a full-face mask is far more difficult to replace underwater, if dislodged, than a half-mask.[2]

Internal layout

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Four types of internal layout can be distinguished.

Open plan

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The simplest arrangement is a single interior space, with no subdivisions, and no mouthpiece. This is most appropriate to free flow systems. In this arrangement the diver can talk clearly, including talking with other divers underwater. This allows communications equipment (usually an intercom wire or by modulated ultrasound) to be installed in the mask and is very useful for working divers.[citation needed] If an open plan full-face mask floods underwater, it can be more difficult to clear than with a mouthpiece.

There also is the problem of "dead space" inside some masks causing risk of carbon dioxide retention. Free flow air supply overcomes these problems by providing so much air that the mask is constantly flushed. The cost is high noise level and very inefficient air usage on some models.[citation needed]

Internal oro-nasal breathing mask

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Ocean Reef Full Face Mask (IDM)

With a small (oro-nasal) breathing mask enclosing the mouth and nose inside the full-face mask, the dead space is considerably reduced, but the smaller space around the mouth increases the distortion of speech.[2]

Internal mouthpiece

[edit]

A mouthpiece with bite-grip connects the gas supply directly to the diver's mouth inside the mask. If the mask floods, the diver can continue to breathe while clearing the mask, and it minimises dead space. Many Royal Navy and frogman's rebreathers have this mask arrangement. It makes clear talking difficult, but not impossible.[citation needed] For many years British armed forces divers used the Admiralty Pattern full face mask, with a long rectangular window, largely flat, and bent back 90° at the ends, as in the illustration of a diver with a CDBA rebreather. The lower skirt has a hole that a breathing set mouthpiece is fitted through.[9]

Mouthpiece on a detachable pod

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Kirby-Morgan makes a unique configuration of full-face mask, the KM-48 Supermask, which has some characteristics of a half mask, while retaining many of the advantages of the full face mask:[10] The rigid plastic main frame of the mask has a rubber skirt which seals around the eyes and nose like a standard half-mask, the nose may be pinched through the rubber nose pocket to equalise in the same way as with a half mask, and there is an extension to the skirt which seals around the lower part of the face and encloses the mouth. This mask has a clip-on pod section which carries the demand valve, and this part seals against the lower part of the frame, allowing the diver to remove the regulator pod when on the surface, or to use an alternative gas supply, which can either be mounted on another pod, or be an ordinary Scuba regulator second stage with a standard mouthpiece. This feature makes it possible to use bailout gas supplied by a dive buddy with a standard regulator while wearing a Supermask. An optional pod with a dive/surface valve for use with rebreathers is available to military users.[11][2]

Attachment of breathing gas supply components

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Demand valve, twin hoses, rebreather mouthpiece or free-flow air supply hose may connect to the mask in various ways, including:-

  • Connection of surface supply and bailout hoses to a bailout block on the mask frame, typically at the right temple. From there integral plumbing takes the air to the integral demand valve and free-flow/defog port.
  • Demand valve rigidly connected to the lower part of the frame, with external bailout block.
  • Demand valve or rebreather mouthpiece plugged into the lower part of the frame.
  • Demand valve plugged into a port on the side of the lower part of the frame (for bailout).
  • Twin hoses ported through the lower part of the window, as in the Siebe Gorman aqualunger's full-face mask.
  • Through the mask's flexible skirt at the bottom, as with Siebe Gorman frogman's masks, for example the Siebe Gorman CDBA.
  • The early DESCO full-face mask's twin breathing hoses entered through the skirt at the sides, level with the lower end of the nose, pointing backwards and a bit downwards, to keep the breathing tubes shorter to reduce the risk of snagging.
  • AGA mask with through-water comms.
    AGA mask with through-water comms.
  • Military diver with full face mask with through-water comms.
    Military diver with full face mask with through-water comms.
  • Kirby-Morgan band mask.
    Kirby-Morgan band mask.
  • CGI image of 2 divers swimming with CDBA British armed forces rebreathers with Admiralty pattern full face masks
    CGI image of 2 divers swimming with CDBA British armed forces rebreathers with Admiralty pattern full face masks
  • Kirby Morgan KM-48 Supermask full face diving mask. Mask and pod split showing mating surfaces
    Kirby Morgan KM-48 Supermask full face diving mask. Mask and pod split showing mating surfaces
  • KM-48 Supermask assembled view from directly in front
    KM-48 Supermask assembled view from directly in front
  • KM-48 Supermask assembled view of inside from back
    KM-48 Supermask assembled view of inside from back
  • KM-48 Supermask assembled, seen from left
    KM-48 Supermask assembled, seen from left
  • KM-48 Supermask assembled view from lower front right
    KM-48 Supermask assembled view from lower front right
  • Draeger Panorama full-face mask with Apeks P-ported demand valve. Upper front view.
    Draeger Panorama full-face mask with Apeks P-ported demand valve. Upper front view.
  • Draeger Panorama profile view from right side
    Draeger Panorama profile view from right side
  • Draeger Panorama inside view from behind.
    Draeger Panorama inside view from behind.

Operation

[edit]

Fitting

[edit]

The full-face mask is generally the last piece of equipment fitted before the dive, as it is cumbersome and makes fitting other equipment more difficult by restricting the diver's field of vision, and the mobility of the head. The fitting may require the help of an attendant, particularly for the heavier band masks. The straps must be tensioned sufficiently to ensure a good seal, and to hold the mask securely to the diver's head, but not so tight as to cause discomfort during the dive. It is possible to adjust the fit to some extent during the dive.[2]

Clearing

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Water which enters the air spaces of the mask may be expelled either under the lower edge of the skirt, or through the exhaust port of the demand valve, or through a drain valve fitted for this purpose.[2]

Equalising

[edit]

The full-face mask must provide a means for the diver to block the nostrils for equalizing the middle ears. This may be provided in several ways. Some masks have a soft rubber nose pocket which allows the diver to pinch the nose directly, some have a soft cushion which can be pressed against the lower part of the nose to occlude the nostrils, and others have a mechanism which applies soft levers to the sides of the nose to pinch it in the same way that it would be done with fingers. The details of these mechanisms varies, but they all work. Some need to be adjusted to suit the individual diver, others are sufficiently flexible to fit almost anyone.[2]

Defogging

[edit]

Most full-face masks do not have fresh airflow directly over the interior of the faceplate, and are to some extent susceptible to fogging by condensation during a dive. This may be minimized by application of a demister surfactant before the dive, by rinsing during the dive, or in those cases where the system allows, by purging the mask through a free-flow/defog valve, which directs a flow of dry air over the inner surface of the faceplate. This facility uses a lot of air, and is usually only available on models intended primarily for surface supplied applications.[2]

Some British Army and Russian gas masks are designed so that when the wearer breathes in, the inflow of air blows over the inside of the mask window and tends to evaporate any mist deposit on it. This feature is also found on the original Kirby Morgan EXO-26 mask, but the later EXO-BR uses an oro-nasal inner mask to reduce dead space.[12][2]

Surface breathing

[edit]

Full-face masks intended for use with scuba may provide a method of switching to atmospheric air when above the surface, to save breathing gas. Rebreather systems often incorporate a dive/surface valve in the mouthpiece which may provide an opening to the ambient environment when the loop is isolated. Some other full-face masks allow the demand valve to be unplugged on the surface, or provide a "snorkel valve" port which can be opened to allow atmospheric air to enter. The small saving on breathing gas is unimportant with surface-supplied breathing apparatus.[citation needed]

Bailout

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See also: Bailout cylinder

Emergency provision of an alternative breathing gas source is required in case of a failure of the primary gas supply. This is managed in several ways by full face masks.

The most prevalent method for masks intended for surface supply applications is known as a bailout valve. The surface supplied diver generally carries a bailout gas supply sufficient to reach a place of safety based on the planned dive profile. This gas supply is regulated by a scuba first stage regulator, and plumbed into the primary air supply circuit via a bailout valve before it reaches the demand valve. The full face masks designed for surface supply work usually mount this valve on the side of the mask frame, in the bailout block, where it is convenient and easily reached by the diver. The bailout cylinder valve is normally open during the dive. To switch to bailout, the diver simply opens the bailout valve, and is immediately supplied by gas from the bailout cylinder.[2]

A similar functionality can be provided for masks without an integral bailout block, by mounting an external bailout block at a convenient place on the diver's harness. Surface supply and bailout supply hoses are connected to this block, which works exactly the same way as the integral block. The same method can be used for open circuit scuba diving, but this only allows for a single gas switch. Gas manifolds with more than two gas supply options are technically possible, but allow for a wider range of operator error and are therefore considered high risk, as the consequences of switching to a gas unsuitable for the current depth may be fatal.[2] This system does not allow for supply of bailout gas to another diver. This system is used for most full face masks, as they have no other option. Surface supplied divers use the pneumofathometer hose to supply gas to another diver.

Rebreather systems which use a bailout valve on the mouthpiece are often the method of choice for use with full-face masks, as the bailout mechanism is provided in the mouthpiece, and works the same whether used with a full-face mask or a half mask.[2]

A few models of full-face mask are provided with secondary ports to which additional demand valves can be connected, either by screw connector (Ocean Reef) or by bayonet style connector (Dräger). These allow for bailout or decompression gas to be ported to the mask via an entirely independent scuba set, but it is necessary to control which gas is used at any given time by using a valve on the supply line or cylinder. The Dräger Panorama mask also allows the primary demand valve to be unplugged from the mask and a bailout demand valve to be substituted. This can be done underwater with very little water ingress to the mask, and is closely equivalent to switching demand valves with a half mask, but a little slower and more complex.[13]

The Kirby-Morgan KM 48 Supermask is unique, in that the airspace for the eyes is completely separate from the mouth area, and the mask can be worn as a half mask by leaving off the mouthpiece pod, which holds the demand valve or rebreather mouthpiece. This allows bailout to a standard scuba demand valve with mouth grip, but also allows the diver to carry bailout gas fitted to a second pod, which can be clipped to the mask when the primary pod has been unclipped. This can be done underwater, and as there is a standard mouthpiece inside the pod, breathing can commence before the pod is fully connected and sealed. The pod can be cleared of water after sealing, and the eye-space is not affected by the switch.[2] A final alternative sometimes used by recreational divers, is to bail out to a standard demand valve by removing the full face mask completely, and then fitting a backup half mask.[2]

Safety

[edit]

It may take a fairly long time to remove the mask to switch to breathing from the atmosphere. To avoid this, some full-face masks have a valve to switch between breathing from the set and breathing from atmosphere. The 'dive/surface valve', or 'snorkel valve', should be easily operated by the diver, even if wearing thick diving gloves, but not projecting so far that it can be easily knocked against things in low visibility water or in the dark, or in hand-to-hand combat underwater.[citation needed]

A full-face mask provides better security of breathing gas supply than a half-mask if there is a risk of the diver losing consciousness underwater.[2]

The mask faceplate is generally a high impact strength polymer which is securely attached to the skirt or frame. A failure of the faceplate can be a life-threatening incident with some full face masks, as the water will flood into the oro-nasal inner mask and compromise the air supply. This problem is avoided by the masks which include a mouthpiece.[2]

Not all divers will get a satisfactory seal from the skirt of any given full-face mask, as face shapes and sizes differ, but most divers will be able to find a mask that works for them. A major flood caused by a temporarily dislodged mask is easily drained by purging after replacing it in the correct position, and adjusting the straps if necessary. Lesser leaks will usually drain automatically from the mask through the exhaust valve of the demand valve or a purge valve fitted for that purpose as long as the mask is orientated with the valve at the low point. If there is too much water in the mask to allow inhalation it can usually be cleared using the purge button on the demand valve.

History

[edit]
See also: History of underwater diving and History of scuba diving

A full face diving mask was invented by Yves le Prieur in 1933.[14]

The free-flow type of full-face mask is also sometimes referred to as a Jack Browne rig, named for a DESCO engineer who designed an early version of a full-face mask with a surface-supplied free-flow air supply.[15][16]

See also

[edit]
  • Self-contained breathing apparatus – Breathing gas supplied respirator carried by the user, many of them have full-face masks.
  • Gas mask – Protection from inhaling airborne pollutants and toxic gases, most gas masks are full-face masks.
  • Diving helmet – Rigid head enclosure for underwater diving
  • Diving mask – Face cover to improve underwater vision

References

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Further reading

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Full-face diving mask

View on Grokipedia
from Grokipedia
A full-face diving mask is a specialized piece of equipment that covers the entire face of the diver, creating a watertight seal to protect the eyes, nose, and mouth from the surrounding water while integrating a demand valve or regulator for breathing from a scuba tank or surface supply. Unlike traditional half-masks that only enclose the eyes and nose with a separate mouthpiece, the full-face design combines vision and respiration in a single unit, typically featuring a transparent for a wide and a skirt for a comfortable, customizable fit. These masks conform to standards such as European EN-250, allowing safe use to depths of up to 150 feet (45 meters) with proper . Developed in the mid-20th century, full-face diving masks evolved from early breathing apparatuses to meet the needs of and divers, with iconic models like the AGA Divator introduced over 70 years ago and remaining in production today due to their reliability in harsh conditions. Key manufacturers such as Interspiro, Kirby Morgan, and Ocean Reef have advanced the technology, incorporating features like multi-strap harnesses for secure attachment, oral-nasal pockets to separate and for efficient gas flow, and adjustable equalization devices that allow relief by pinching the through caps. Many models include ports for communication systems, enabling clear voice transmission via integrated microphones, which is particularly valuable for team-based operations. Full-face masks offer several advantages for various diving applications, including enhanced protection against cold water, contaminants, and impacts, which reduces jaw fatigue and prevents issues like numb teeth during prolonged dives. They facilitate natural breathing through both the and , promoting a more relaxed experience and easier equalization compared to traditional regulators, while internal air circulation helps prevent visor fogging. Recreational divers appreciate the expanded and comfort, while public safety and commercial divers rely on them for operations in contaminated environments or requiring verbal coordination. However, disadvantages include challenges with equalization for some users, complications in procedures such as air-sharing or mask removal that simultaneously affects vision and breathing, and potential impacts on control. Their use demands specific training, such as the PADI Full Face Diver course, to master skills like regulator attachment, removal, and purge procedures, as improper handling can complicate air-sharing or mask clearing.

Introduction

Definition and purpose

A full-face diving mask (FFM) is a specialized piece of that covers the entire face of the diver, creating a watertight seal to exclude water while integrating the functions of a traditional for vision and a second-stage regulator for delivery into a single unit. This design differs from conventional half-masks, which cover only the eyes and and require a separate mouthpiece for inhalation. The primary purpose of a full-face diving mask is to provide clear, unobstructed through a transparent faceplate while simultaneously enabling natural through both the and mouth via an internal demand valve system that supplies on . These masks must conform to standards such as European regulation EN-250, allowing safe use to depths of up to 150 feet (45 meters) with proper certification. It also serves to protect the diver's face from environmental hazards, such as cold that could cause discomfort or , and contaminants in the that might irritate the eyes, , or . By maintaining a sealed breathable around the entire face, the mask protects the airway from ingress, offering a potential survival benefit for an unconscious diver if connected to a reliable gas supply. Full-face diving masks are applied across various diving activities, including recreational and technical for improved comfort and visibility, as well as in commercial, public safety, and scientific contexts where communication and protection are critical. They are particularly valued in scenarios requiring team coordination, such as search-and-recovery operations or adaptive diving for individuals unable to use traditional mouthpieces. The mask's full-face seal facilitates simultaneous nasal and oral , reducing and allowing for easier equalization of during descent.

Advantages and disadvantages

Full-face diving masks offer several advantages over traditional separate mask and regulator combinations, primarily in terms of comfort and usability. The full coverage eliminates the need for a mouthpiece, reducing fatigue during extended dives by allowing natural mouth relaxation and breathing. This design also enhances communication, as divers can speak clearly underwater without removing the regulator, facilitating better interaction among dive teams or with surface support through integrated systems. Additionally, the sealed structure provides superior protection against water ingress, cold temperatures, and environmental pollutants, making it particularly beneficial in contaminated or hazardous conditions. For beginners, the integrated setup simplifies gear management by reducing the number of components, allowing easier and less intimidation compared to juggling a separate and regulator. Despite these benefits, full-face masks have notable disadvantages that can impact their practicality. They are significantly more expensive, with prices ranging from $340 to over $1,600 depending on the model and features, compared to basic traditional setups under $200. The bulkier design increases hydrodynamic drag and weight, potentially affecting trim and swimming efficiency during dives. Potential issues include fogging of the larger faceplate, which requires ongoing maintenance with treatments, and the risk of elevated (CO2) buildup in the mask's dead space if ventilation is not properly managed, leading to higher reinspired CO2 levels that exceed standard limits in some models. Furthermore, while equalization is often straightforward at shallow depths, deeper dives can present challenges due to the sealed enclosure, requiring specific techniques to manage without direct pinching.

Design and Function

Basic operation

A full-face diving mask (FFDM) operates by enclosing the entire face, including eyes and , within a rigid frame and flexible that forms a watertight seal against ambient water pressure. This design allows for pressure equalization across the face seal, where external hydrostatic pressure is balanced by delivering internally to the mask's interior volume, preventing collapse or leakage at depth. The diver inhales through a demand regulator integrated into the mask, drawing in fresh gas from the supply source, while exhaled gas is directed through one-way valves to exit via exhaust ports, maintaining a continuous flow without flooding. These designs conform to standards such as EN 250:2014 for breathing performance. To prevent carbon dioxide (CO₂) buildup, FFDMs incorporate dead space management, which minimizes the volume of exhaled gas retained within the mask that could be rebreathed. This is achieved through a small internal chamber or baffle system that separates and paths, ensuring that fresh gas fills the primary zone while CO₂-laden exhalations are promptly vented; effective management through baffle systems and oronasal pockets minimizes dead space to reduce CO₂ buildup and risk, though it is generally larger than in traditional mouthpiece setups, necessitating proper sizing and training. Vision and breathing in an FFDM are seamlessly integrated, as the diver breathes normally through the nose and mouth without needing a separate oral snorkel or regulator bite, enabling hands-free operation and reduced jaw fatigue. The transparent faceplate provides a wide field of view, typically 180 degrees or more, while the internal gas delivery supports clear visibility by keeping the interior dry and fog-free through positive pressure and anti-fog coatings. These masks are generally suitable for depths up to 50-60 meters depending on the model and certification standards, though seal integrity and gas supply must be considered at greater depths.

Gas supply integration and positive pressure

Full-face diving masks integrate breathing gas supplies through several methods tailored to different diving configurations. In scuba setups, a second-stage demand regulator attaches directly to the mask via a quick-disconnect fitting on a low-pressure hose from the first-stage regulator on the diver's cylinder, allowing on-demand gas delivery. Surface-supplied systems connect via an umbilical hose to a gas distribution block on the mask, enabling primary supply from the surface and switching to emergency bailout cylinders if needed. Some advanced models incorporate built-in demand valves as part of the mask assembly for seamless integration across scuba, surface-supplied, or rebreather applications. Positive pressure features in these masks maintain a slight overpressure inside the mask—typically 20–35 mm of water (about 200–350 Pa) above ambient—to prevent water ingress or contamination, even with minor seal imperfections. This is achieved through specialized valve mechanics in the breathing apparatus: upon inhalation, the demand regulator supplies gas to equalize and exceed ambient pressure, while exhalation directs airflow through one-way exhaust valves to ensure unidirectional flow and avoid rebreathing. The system activates automatically with the first breath or via a manual switch, promoting safety in harsh environments like cold or polluted water. The system maintains positive pressure, and exhaust valves prevent excessive buildup by allowing surplus gas to vent unidirectionally. While positive pressure systems markedly reduce flooding risks by expelling potential leaks as air bubbles rather than allowing water entry, they necessitate regulators certified for full-face mask use, which must deliver sufficient peak flow (at least 300 liters per minute) and handle the mask's internal volume without free-flow issues or inadequate supply.

Construction

Faceplate and frame

The faceplate of a full-face diving mask serves as the primary viewing window, typically constructed from or to balance optical clarity with impact resistance. provides superior scratch resistance and light transmission for undistorted underwater vision, while offers enhanced shatter resistance, making it suitable for rugged commercial or military applications. The frame, which secures the faceplate, is generally made from rigid polymers or composites such as glass-filled or high-impact ABS plastic, ensuring structural integrity under without adding excessive weight. These materials are chosen for their resistance in saltwater environments and ability to maintain a low internal , which facilitates easier ear equalization during descent by reducing the air space that needs to be compressed. For instance, models like the OceanReef III feature a frame design that achieves 24% smaller internal compared to similar masks, aiding management. Anti-fog coatings are applied to the faceplate during manufacturing to prevent buildup, often through chemical treatments or integrated systems that allow purging with exhaled air. Lens curvature is optimized for a wide , commonly providing up to 180 degrees of peripheral vision, which exceeds that of traditional half-masks and enhances . Variations in faceplate design include single large lenses for panoramic visibility, predominant in full-face masks, versus adaptations with dual-lens inserts for prescription corrections. Single-lens configurations, as in the OTS Spectrum, allow for custom prescription overlays directly on the , while some models like the Ocean Reef Neptune support modular inserts to accommodate individual vision needs without compromising the seal.

Seals and straps

The seals and straps of full-face diving masks are critical for maintaining a watertight barrier against the face and securing the mask during underwater operations. Face seals typically employ soft skirts that conform to the diver's contours, providing a comfortable and reliable seal without excessive pressure on the skin. These skirts are molded from high-grade liquid , often featuring a or spring profile design to enhance adaptability and sealing surface area, such as the double-sized sealing (30-45 mm spacing) in models like the Ocean Reef Neptune series. In commercial diving applications, band-mask variants utilize elastic rubber bands integrated into the head harness for rapid donning and doffing, allowing quick deployment in demanding environments like surface-supplied operations. Strap mechanisms commonly consist of multi-strap systems, such as the five-strap rubber harness in the Interspiro Divator mask, which uses buckles for precise adjustment and secure locking to accommodate various head sizes. Similarly, the Kirby Morgan M-48 SuperMask employs a four-point semi-stretch harness with quick-release buckles and strap keepers, distributing tension evenly across the head for stability. These adjustable designs integrate with the mask frame to ensure even pressure on the seal, minimizing slippage under dynamic conditions. The skirts in these masks balance comfort and durability through varying ratings, typically in the Shore A 40-50 range, where softer formulations (e.g., around 10-30 Shore A for the inner seal) prevent during extended wear while firmer outer sections resist deformation. Seals are engineered to withstand pressure differentials up to 4 bar, equivalent to approximately 40 meters of depth, as demonstrated by the operational limits of masks like the Kirby Morgan M-48, which supports dives to 39 meters under CE certification for both SCUBA and surface-supplied modes.

Internal layout and breathing components

The internal layout of a full-face diving mask typically features compartmentalized designs to optimize and maintain clear zones. Common configurations include open-plan layouts that allow free across the mask's interior volume, internal oro-nasal masks that separate and paths to prevent rebreathing of exhaled gases, and detachable regulator pods that integrate mouthpieces for modular regulator attachment. Key breathing components consist of baffles and one-way valves that direct gas flow efficiently while minimizing dead space, which is typically 100-200 ml in well-designed systems to reduce buildup. Baffles, such as exhaust isolation chambers or oral-nasal cups, separate intake and exhaust areas to limit mixing of fresh and exhaled air. valves, often two in number, permit ambient or supplied gas entry into the breathing zone, while adjustable valves route bubbles away from the faceplate to avoid visual obstruction and further minimize dead space. Oro-nasal designs incorporate a soft pocket covering the nose and mouth, enabling natural nose and mouth breathing without the need to bite a traditional mouthpiece, thereby reducing during extended dives. Attachment points for regulators are positioned internally within the mask frame, such as frontal or lateral ports connected via low-pressure hoses, ensuring seamless integration without external protrusions that could snag or compromise hydrodynamics.

Operational Use

Fitting and donning

Fitting a full-face diving mask begins with size selection, which is typically based on precise face measurements to ensure a secure seal without discomfort. Manufacturers like Ocean Reef provide measuring kits with to determine if a small/medium or medium/large size is appropriate, referencing standardized charts such as those from the Los Alamos Scientific Laboratory. Similarly, some models, such as the OTS Guardian, are designed as a single size to accommodate a wide range of facial dimensions, relying on adjustable harnesses and double-seal skirts for versatility. Once the appropriate size is selected, donning the mask involves positioning it correctly on the face before securing the straps. Start by aligning the chin with the mask's base and ensuring the skirt lies flat against the skin, avoiding any interference from hair, hoods, or . Extend all straps fully, then pull the mask over the head, tightening the lower straps first for even tension around the and cheeks, followed by the temple and upper straps. For multi-strap systems, such as the six-strap in the Ocean Reef Neptune Space, adjust the middle straps initially, then the bottom and top ones to achieve balanced pressure without twisting. Overtightening, particularly at the top, can distort the frame and cause leaks or fatigue, so tension should be firm yet comfortable. A critical step in fitting is the seal check, performed via an inhale test on the surface to verify no air leaks. Place the mask on the face without straps or with them loosely adjusted, then inhale gently through the ; the mask should suction slightly without gaps, especially at the temples, cheeks, and under the . Proper fit ensures minimal gaps, with no more than 1-2 mm separation at sensitive areas like the temples to prevent water ingress under pressure; larger gaps indicate the need for readjustment or a different size. seals, common in full-face designs, enhance this by conforming to facial contours. Considerations for facial hair include shaving closely for optimal sealing, as beards or mustaches can compromise the skirt's contact with the skin, potentially requiring silicone-based sealants or alternative models with enhanced double seals. For glasses wearers, regular eyeglasses are incompatible due to seal interference, but prescription lens inserts designed for single-faceplate masks, such as Scuba Spec systems, can be fitted inside to maintain clear vision without disrupting the seal. Before entering the water, apply a pre-dive defogging agent, such as a commercial anti-fog spray or solution, evenly inside the faceplate and orinasal area to prevent lens fogging from . Rinse gently with afterward to remove residue, ensuring the mask's internal air circulation features are not obstructed.

Underwater procedures

During a dive, maintaining the integrity of a full-face diving mask involves specific procedures to address common issues like water ingress, pressure equalization, and lens fogging, all while keeping the mask in place due to its integrated regulator and communication features. Clearing a flooded mask typically requires the diver to exhale forcefully through the while tilting the head back slightly to direct water toward the exhaust valve or purge mechanism. This technique leverages the mask's internal layout, such as the orinasal pocket, to channel exhaled air and expel water through dedicated valves without removing the mask. Ear equalization in a full-face mask is adapted from standard Valsalva maneuvers, using the mask's built-in nose pocket or equalization block to gently pinch the nostrils. The diver presses the top of the mask or a dedicated front cover to seal the nostrils with caps, then exhales mildly through the nose to equalize , ensuring comfort during descent without disrupting the . This method accommodates the mask's sealed design, preventing air loss or water entry during the process. To prevent or address fogging underwater, divers apply treatments like diluted to the lens interior before donning, creating a thin film that withstands submersion; integrated systems in some models, such as hydrophobic coatings, further reduce . Spit-based methods are generally avoided in full-face masks, as can compromise the skirt's seal over time, leading to leaks. If minor fogging occurs, a small amount of can be introduced and cleared via the standard exhale technique to rinse the lens.

Emergency and surface operations

In emergency situations during a dive, the bailout procedure for a full-face diving mask typically involves switching to an alternate air source while attempting to retain the mask, or performing an emergency doffing if the mask floods severely. For low air warnings, divers open the —such as by rotating a side block handle fully anticlockwise—to access reserve air from a pony bottle or integrated supply, breathing normally without holding breath to avoid . If out of air entirely, the diver exhales slowly, removes the mask by pushing the lower tabs outward, switches to a buddy's or personal backup regulator, clears it, and breathes normally while ascending. This process must be practiced in controlled environments like shallow pools to ensure proficiency, as full-face masks increase the complexity compared to traditional setups. Bailout valves in full-face masks facilitate rapid purging of or , often clearing the mask in 3 to 15 seconds depending on the model and method, such as holding the purge button while tilting the head. For instance, in the Guardian model, tilting the head back at 45 degrees and purging for 3 seconds followed by a forceful exhale clears flooding effectively. Divers should always carry a spare traditional in a BCD for immediate replacement if the full-face unit fails. At the surface, full-face masks support breathing via free-flow or demand valve modes, enabling snorkel-like use above water when integrated with surface-supplied air or open-circuit systems. The Ambient Breathing Valve (ABV), turned counterclockwise to open, allows ambient air intake but requires the mask to be fully out of the water; it must be closed clockwise before descent to prevent free-flow issues underwater. Surface use is limited to calm conditions to avoid wave action breaching the skirt seal, which could lead to water ingress or loss of fit. Divers monitor for CO2 buildup, or , through symptoms such as increased breathing rate, headache, , confusion, and disorientation, which can arise from rebreathing in masks with higher dead space. Upon detection, procedures include signaling the buddy, ascending immediately, and switching to a backup air source if needed, as elevated CO2 can impair judgment and escalate to . Training emphasizes recognizing these signs early to prevent escalation.

Safety Considerations

Associated risks

Full-face diving masks, while offering advantages in comfort and communication, present several specific hazards that can compromise diver safety if not managed properly. One primary is flooding, which can lead to aspiration of water or other substances into the lungs. If the mask seal is compromised or if occurs—potentially triggered by seasickness, , or ingested food particles—gastric contents may become trapped within the oronasal compartment, obstructing airways and increasing the likelihood of asphyxiation. A documented case involved a commercial diver at 42 meters who succumbed to aspiration of vomitus obstructing the tracheobronchial tree while using a full-face mask (FFM). Another significant concern is (CO2) retention due to inadequate ventilation within the mask's dead space, the volume of air rebreathed between and . Full-face masks typically feature dead spaces ranging from 200 to 340 milliliters, exceeding the physiological dead space of approximately 150 milliliters and thereby elevating inspired CO2 levels, particularly during exertion or at depth. This rebreathing can result in , with end-tidal CO2 rising by up to 0.30 kPa under high workloads, leading to symptoms such as , , rapid , , and impaired judgment—effects exacerbated in the enclosed breathing environment of the mask compared to traditional mouthpieces. Fogging of the faceplate represents an additional hazard, as condensation from exhaled moisture or temperature differentials can obscure vision, causing disorientation and potentially leading to navigational errors or collisions underwater. This issue is more pronounced in full-face designs due to the larger enclosed volume and integrated regulator paths, which may trap humid air against the lens. Novice divers face heightened panic risks with full-face masks owing to unfamiliarity with the enclosed system; for instance, an inexperienced diver on a wreck dive at 18-24 meters experienced rapid air consumption and anxiety when air supply failed, necessitating mask removal without a backup, which amplified stress during ascent. Entrapment during emergency removal poses further dangers, as the mask's full coverage and securing straps can make it challenging to quickly detach , especially if the diver must simultaneously manage from an alternate source. In one incident, a diver with a hypersensitive gag reflex struggled to remove the mask at depth after running out of air, requiring them to pinch their and close their eyes to prevent water entry, thereby increasing potential. Pressure-related seal failures become more likely beyond moderate depths, where unequalization or structural stress can breach the perimeter seal, allowing water ingress. Recent reports highlight regulator incompatibility issues, such as leaks from non-approved in integrated systems; a reported incident with an Interspiro full-face mask involved a third-party failure, underscoring risks from mismatched components that can cause air loss or flooding.

Mitigation strategies and training

To mitigate risks associated with full-face diving masks, such as potential flooding, divers must prioritize regular and pre-dive inspections. Seals and valves should be visually inspected before each use for cracks, wear, or deformation, with a focus on the silicone face seal and exhaust valves to ensure airtight integrity and proper airflow. Annual professional inspections are recommended for all components, including the regulator integration and frame, or after 80 to 100 dives, whichever occurs first, to detect subtle degradation that could compromise safety. Only certified regulators compatible with the mask model should be used, as verified by manufacturer specifications, to prevent airflow restrictions or leaks. Post-dive care involves rinsing the mask in and storing it in a protective case away from to preserve seals. Buddy checks play a critical role in confirming fit and functionality before entering the water. During the pre-dive BWRAF sequence (Buoyancy compensator, Weights, Releases, Air, Final okay), a partner should verify the mask's seal by gently pressing around the edges while the diver nods and shakes their head to simulate movement, ensuring no slippage or gaps. This step, combined with testing the regulator purge and communication if equipped, helps identify issues like loose straps or improper seating that could lead to water ingress. Training through certifications like the PADI Full Face Mask Diver specialty course is essential for safe use, emphasizing mask-specific skills beyond standard open-water training. The course covers donning and doffing procedures, equalization techniques adapted for the enclosed design, and emergency responses, including switching to a backup regulator. Simulated flood drills are a core component, where divers practice partially or fully flooding the mask in confined water and clearing it by exhaling forcefully through the nose while sealing the bottom edge, building confidence in managing water entry without panic. Equivalent programs from agencies like SDI/TDI require at least two open-water dives to demonstrate proficiency in these skills, typically for divers aged 10 or older with prior open-water . Such specialized significantly enhances , with studies showing that adherence to pre-dive checklists and protocols reduces the incidence of mishaps by 32% overall (36% for major mishaps) in . Dive agency data from organizations like DAN indicate that proper preparation and skill practice lower overall incident rates, particularly for equipment-related issues like flooding. Recent advancements in technology, integrated into recent full-face models, further support mitigation by addressing visibility loss in older designs. Pre-treated coatings on lenses provide long-lasting defogging without manual application, reducing distraction and enhancing focus during dives. These innovations, combined with barriers isolating the breathing area, minimize condensation buildup and are recommended for models used in varied conditions.

History and Development

Origins and early models

The origins of the full-face diving mask trace back to the early , with French inventor Yves le Prieur patenting a design in 1933 that integrated a with a full-face enclosure for underwater use. Development accelerated in the 1940s for military purposes during . One of the earliest designs was patented by Victor Berge on March 4, 1941 (U.S. 2,303,155), featuring a rigid full-face enclosure with provisions for air supply hoses, intended for naval and amphibious operations such as troop landings from submarines or surface vessels. Produced by the Ohio Rubber Company, this mask was distributed to Allied forces under the Lend-Lease Act and represented an advancement over partial masks by providing facial protection and integrated for shallow-water combat diving. Concurrently, the U.S. Navy adopted the Jack Browne mask in the mid-1940s as a lightweight, free-flow full-face option for emergency escapes and shallow reconnaissance. This rubber mask, manufactured by DESCO, included a breather bag and surface-supplied air delivery, enabling divers to operate in contaminated or cold waters without separate goggles or mouthpieces; it saw extensive use in WWII training and salvage operations but was limited to depths under 20 feet due to pressure equalization challenges. In the , German manufacturer Dräger advanced surface-supplied through innovations, including regulators like the PA40 used with full-face masks for industrial tasks such as underwater welding and . These systems emphasized and compatibility with umbilical air supplies, marking a shift toward professional applications beyond military needs. By the , rigid band-mask designs emerged for industrial use, exemplified by the AGA full-face mask from the Swedish firm AGA (later Interspiro). This model employed a positive-pressure mechanism with a skirt and metal frame to ensure a watertight seal, facilitating communication via integrated microphones and serving sectors like offshore oil extraction and harbor maintenance. Ocean Reef introduced scuba-compatible variants in the late , adapting demand regulators for self-contained systems, though seal limitations initially limited operations to depths up to 100 feet (30 meters). The first recreational models arrived in the late , but high costs—often over $500—hindered widespread adoption among divers. In the , full-face diving masks advanced significantly through the integration of communication modules, enabling clear voice transmission for coordination in professional and recreational settings. These systems, often built-in with and speakers, eliminated the need for separate mouthpieces and enhanced safety during complex dives. Concurrently, heads-up display (HUD) technology emerged, projecting critical dive data such as depth, air supply, and navigation directly onto the mask's visor for hands-free monitoring. Innovations in materials and have included advanced coatings on visors to maintain clarity in varying water temperatures and humidities. Manufacturers also adopted lighter polymer composites for mask frames, improving comfort during extended use without compromising structural integrity. The Interspiro Divator series features optimized airflow dynamics with positive pressure breathing valves, supporting efficiency at depths up to 100 meters (328 feet). Market trends indicate steady growth in the full-face diving mask sector, with the global integrated diving masks segment projected to reach approximately $773 million by 2025, fueled by rising participation and eco-conscious tourism emphasizing low-impact exploration. Professional applications continue to favor durable models from Kirby Morgan, such as the M-48 MOD-1, valued for their ruggedness in commercial operations. In contrast, consumer-oriented brands like Ocean Reef have gained traction with user-friendly designs, such as the Neptune series, suited for sport divers seeking integrated regulators and wide-field visibility. Post-2020, full-face snorkel masks experienced heightened adoption for shallow-water , particularly in tropical destinations, due to their ease of use and panoramic views that appeal to novice participants in guided eco-snorkeling tours. This surge aligns with broader recovery in , though safety guidelines emphasize proper fit to mitigate risks like CO2 buildup.

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