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At this time, several technical scuba agencies developed formal sidemount training programs and incorporated sidemount diving configuration as an equipment option within existing technical diving programs.
At this time, several technical scuba agencies developed formal sidemount training programs and incorporated sidemount diving configuration as an equipment option within existing technical diving programs.


When [[PADI]] instructor, Jeff Loflin,<ref name="Jeff Loflin" /> devised a distinctive sidemount diving speciality course, it proved extremely popular, being replicated by many PADI technical-level instructors. This soon led to PADI devising standardised sidemount diving programs at both recreational and technical levels – truly cementing sidemount as an increasingly attractive and mainstream option for both recreational and technical divers alike. Other agencies, such as ANDI,SSI,[http://en.wikipedia.org/wiki/Technical_Diving_International TDI] and UTD also incorporate sidemount training at varied levels.
When [[PADI]] instructor, Jeff Loflin,<ref name="Jeff Loflin" /> devised a distinctive sidemount diving speciality course, it proved extremely popular, being replicated by many PADI technical-level instructors. This soon led to PADI devising standardised sidemount diving programs at both recreational and technical levels, making sidemount a viable and mainstream option for both recreational and technical divers. Other agencies, such as [[American Nitrox Divers International|ANDI]], [[Scuba Schools International|SSI]], [[Technical Diving International|TDI]] and [[Unified Team Diving|UTD]] also incorporate sidemount training at varied levels.


== Configurations ==
== Configurations ==

Revision as of 18:28, 1 March 2013

For the grappling position, see Sidecontrol.

Sidemount diver pushing a cylinder in front

Sidemount is a scuba diving equipment configuration which has diving cylinders mounted alongside the diver, below the shoulders and along the hips, instead of on the back of the diver. It began as a configuration popular with advanced cave divers, as smaller sections of cave can be penetrated and tanks can be changed with greater ease. The same benefits for operating in confined spaces were also recognized by divers who conducted technical wreck diving penetrations.

Sidemount diving is now growing in popularity within the technical diving community for general decompression diving,[1] and is becoming an increasingly popular specialty training for recreational diving, with several diver certification agencies offering recreational and technical level sidemount training programs.[2][3][4]

Terminology

Sidemount diving
Sidemount diving is the, now increasingly formalized, approach towards conducting dives with 2 or more primary cylinders secured at the side of the body and in line with the torso – with no cylinders on the diver’s back.[5] A common feature that defines sidemount configuration is the use of bungee cords to provide an upper attachment on the cylinder valve, normally routed from behind the diver’s upper back, whilst the lower cylinder is secured to the diver’s lower harness (butt-plate or waist D-rings) via bolt-snaps.[6]
Sidemount staging
Sidemount staging is the practice of using sidemount configuration (bungee loops and/or buttplate rails) as a means for stowing stage/deco cylinders in a streamlined manner against the sides of the torso, when otherwise diving in back-mounted doubles or CCR.[7]
Stage-only diving
Stage-only diving is the use of standard deco/stage cylinder configuration, without back-mounted cylinders, on an otherwise standard, or partially modified tec/rec BCD. The lower cylinder is attached to waist D-Rings and the upper cylinder to shoulder D-Rings, both via direct bolt-snap. Some divers (untrained in specific sidemount diving techniques) often incorrectly assume this approach to be sidemount diving. No bungee cord is utilised in the upper attachment, causing the cylinders to hang low beneath the diver and not in line (parallel) with their torso beneath their armpits. Without modification of the BCD design, the lack of back-mounted cylinders also causes taco’ing of wing designs and considerable instability.
Monkey diving
Monkey diving is the use of sidemount configuration/procedures, whilst only carrying a single cylinder. It is presented as an option on some recreational level sidemount courses (dependant on agency) and may also be a considered strategy for certain overhead-environment (cave/wreck) penetrations. The use of a single cylinder may require a strategy of counter-weighting to prevent diver instability in the water, depending on the buoyancy of the chosen cylinder.
No-mount diving
No-mount diving is a specialized overhead-environment strategy for dealing with particularly tight restrictions.[8] This may involve divers wearing a very basic harness under their existing configuration, or simply hand-carrying cylinders. Upon reaching a restriction through which they couldn’t otherwise pass, they will ‘strip down’ out of their primary gear, hand-hold or attach a cylinder/s to their ‘no-mount’ harness and move forwards.[8] A ‘no-mount’ harness can consist of nothing more than a weight-belt with several D-rings attached. The evolution of sidemount techniques and configurations has largely made this approach unnecessary, as a minimalist sidemount harness/BCD can be worn beneath back-mounted doubles, or even a CCR.
  • Sidemount divers on the USS New York shipwreck, in Subic Bay, Philippines
    Sidemount divers on the USS New York shipwreck, in Subic Bay, Philippines
  • Divers wearing 3 tanks (2 primary/1 deco) on practice dives during a PADI Tec Sidemount training course
    Divers wearing 3 tanks (2 primary/1 deco) on practice dives during a PADI Tec Sidemount training course
  • Cylinders and equipment for a technical sidemount dive. 2 primary and 1 deco tank per diver. Sidemount BCD shown is a Hollis SMS50.
    Cylinders and equipment for a technical sidemount dive. 2 primary and 1 deco tank per diver. Sidemount BCD shown is a Hollis SMS50.
  • Sidemount diver using an OMS Profile adapted wing BCD
    Sidemount diver using an OMS Profile adapted wing BCD
  • Sidemount diver on a wreck dive in the Philippines.
    Sidemount diver on a wreck dive in the Philippines.

Benefits

Flexibility

The sidemount diving approach offers divers significant benefits to the flexibility of their approach. Unlike back-mounted doubles, acquiring and transporting sidemount suitable cylinders is often much more convenient and accessible. Sidemount diving configuration allows the travelling diver to conduct technical and/or overhead environment dives without having to source traditional back-mounted cylinders. When diving in remote locations, the transportation of diving logistics, especially by hand, is considerably less physically taxing.[9][10]

Sidemount diving equipment is also considerably lighter, and less bulky than back-mounted alternatives – allowing for easier and cheaper (considering the rate of many airline’s excess baggage costs) travel.[citation needed]

Accessibility

Unlike back-mounted cylinders, the sidemount diver has immediate access to, and observation of, the regulators and tank valves of their cylinders. This enables immediate problem identification and allows swifter resolution, without recourse to ‘behind the head’ shut-down drills that require a higher level of mobility, flexibility and freedom to operate.

Streamlining

Sidemount diving configuration places the cylinders under the diver’s armpits, in line with their body. This decreases water resistance (improving air consumption and reducing fatigue) whilst also allowing the diver to pass through smaller restrictions than would otherwise be possible in back-mounted cylinders. The flexibility to remove tanks, and propel them in front, allows the diver to pass through very small passages and holes when penetration diving – being limited only by the size of their bodies and exposure protection.[11]

Safety

Increased accessibility to life-supporting regulators, first-stages and valves improves efficiency and speed of critical cylinder shut-down procedures, allows immediate gas-loss identification and provides the diver with quick access to alternative safety procedures; such as regulator swapping (between cylinders), valve-‘feathering’ to access gas within a cylinder whose regulator is malfunctioned/free-flowing... or even breathing directly from a tank valve.

In addition, stowage of the cylinders next to the diver’s torso, and beneath his armpits, serves to protect vulnerable valves and regulator first-stages from collision, impact and abrasion damage, or accidental shut-down through contact with a ceiling. It also significantly reduces the risk of entanglement behind the diver, where it is least easy to rectify.

Comfort

Many divers will testify that sidemount diving configuration offers greater stability and easier-to-attain trim and control in the water. It is also less physically tiring to carry, and get into, sidemount equipment than with traditional back-mounted doubles – especially when operating from a small boat or a rough shore entry.[12]

The ability to attach, remove and replace cylinders whilst in the water allows the diver to avoid ever having to carry heavy-weight back-mounted cylinders. This is combined with reduced physical exertion when conducting regulator shut-down procedures, which is a major benefit to technical divers who suffer from shoulder or back discomfort or reduced mobility from old injuries.

Redundancy of gas

Whilst technical divers have always utilized a redundant gas system, either isolated-manifold or independent back-mounted cylinders, recreational divers have traditionally resorted to using ‘pony cylinders’ or ‘ascent bottles’ as contingencies against out-of-air emergencies. Whether attached to the primary cylinder, or slung at the chest, these cylinders often presented problems with stability and streamlining, whilst simultaneously only providing a bare minimum supply of air for emergency ascent.

Sidemount diving with two cylinders helps resolve stability and streamlining issues, and ensures that a truly capable redundant supply of air is maintained.

Technical divers debate the pros and cons of independent cylinders versus isolated-manifold doubles. Back-mounted manifold cylinders provide easy access to complete gas supplies, in the event of a regulator failure and shut-down. However, the manifold itself creates additional o-ring failure points and a failure in that component will deprive the technical diver of, at least, one-half of his remaining gas supply. Independent cylinders, when sidemounted, provide true gas redundancy, whilst offering access (via switching regulators between cylinders or feather breathing[13]) of all remaining gas.

  • Sidemount diver removes a cylinder on ascent.
    Sidemount diver removes a cylinder on ascent.
  • Sidemount diver using an adapted wing BCD (OMS Profile with 32lb Donut Wing and soft backplate)
    Sidemount diver using an adapted wing BCD (OMS Profile with 32lb Donut Wing and soft backplate)
  • Sidemount diver explores a wreck penetration.
    Sidemount diver explores a wreck penetration.
  • Sidemount diver partially removes (forward rotates) both primary cylinders to permit passage through a restriction in a wreck.
    Sidemount diver partially removes (forward rotates) both primary cylinders to permit passage through a restriction in a wreck.

History

The 1960s - UK sump diving

The concept of sidemounting cylinders originated from cave diving in the UK, during the 1960s. During 'dry' explorations of Wookey Hole, the River Axe and other underground systems, divers occasionally encountered submerged passages that blocked further exploration. These cavers began incorporating scuba equipment specifically to progress beyond underwater areas. However, because they operated in very confined spaces, and most exploration remained primarily 'dry', they began experimenting and improvising with extremely minimalist configurations, minimising bulk, allowing cylinders to be easily removed and replaced, and retaining the capacity to squeeze through the tightest restrictions.[10][14]

The nature of these 'dives' in cramped sumps did not prioritize the need for buoyancy control or underwater propulsion – so the bare minimum needed was a mask, a cylinder, a regulator, a method of attachment to the body and, only on rare occasions, a set of fins.[8]

Many of these early sump explorers adopted an approach based upon a sturdy belt, with attached cam-band, that allowed a cylinder to be dropped in and carried alongside the outer thigh. This allowed them to crawl, or wriggle, through the dry cave sections, whilst presenting a secure method of attachment for passing through submerged areas.[8] Swimming efficiency, reduced water resistance, trim and buoyancy control were not generally required due to the nature of those caves. At the time, this approach to 'wet' cave exploration was generally called the 'English System'.[15]

The 1970s - Florida

During the 1970s the 'English system' began to be incorporated by American cave divers, operating in Florida.[8] Those cave systems were predominantly 'wet' and involved prolonged swimming with SCUBA; thus more emphasis was paid towards developing the diving performance of the system, in particular buoyancy and trim. Divers required buoyancy control devices for extended fining and began shifting the location of the cylinders from against the thigh, up to the armpit and against the torso.

These exploratory level cave divers began by making their own systems, using and adapting 'off-the-shelf' SCUBA equipment for their needs or creating configurations ‘from scratch’, based upon webbing harnesses and improvised bladders for buoyancy. One popular approach to improvised bladders was the MSR Dromedary hydration system (like a 'Camelbak'), which would be sewn or bolted to the rear of the harness and operated by orally inflating and deflating through the adapted 'drinking tube'.

The 1990s - release of first commercial rig

In the mid-1990s, Dive Rite produced the first commercial sidemount diving system, focused on the newly released 'Transpac' harness. Other cave divers continued to manufacture their own DIY configurations.

At this time, the use of sidemounted configuration was primarily restricted to a small number of exploration-grade cave pioneers.

The 2000s - cave diving popularity and sidemount evolution

The widespread popularity of sidemount diving systems did not emerge until the mid-2010s, when the growing popularity of technical and cave diving became exposed to sidemount proponents on the internet who were offering an alternative approach that matched the minimalism and functionality of the popular 'DIR/Hogarthian' back-mounted systems, whilst offering advantages in flexibility, comfort, accessibility and – highly debated online – safety.[16]

The increasing interest in sidemount diving configurations prompted several manufacturers and individuals to design and sell their own designs of a sidemount system. Hollis, OMS, UTD developed equipment, while Steve Bogaerts (a UK-born cave pioneer, who lives and cave-dives in Mexico) released the very popular 'Razor' system and began teaching a specific model training program for his rig.

At this time, several technical scuba agencies developed formal sidemount training programs and incorporated sidemount diving configuration as an equipment option within existing technical diving programs.

When PADI instructor, Jeff Loflin,[17] devised a distinctive sidemount diving speciality course, it proved extremely popular, being replicated by many PADI technical-level instructors. This soon led to PADI devising standardised sidemount diving programs at both recreational and technical levels, making sidemount a viable and mainstream option for both recreational and technical divers. Other agencies, such as ANDI, SSI, TDI and UTD also incorporate sidemount training at varied levels.

Configurations

Various harness/BCD configurations have been used to sidemount cylinders. The choice between different configuration approaches is typically determined by the nature of the diving undertaken (open water, technical, wreck or cave) and by the divers' existing equipment, financial budget and whether they have a preferred approach to diving philosophy (minimalist, DIR, Hogarthian, etc). The size/ material/ volume of diving cylinders to be used also has a large impact on sidemount BCD requirements.[18][8]

Backplate and wing harness adaptation

Rigid Hogarthian style backplate and wing BCD systems may be modified by adding butt-plates, bungee cords and optional special sidemount buoyancy compensators. Cylinders are supported at the valve end by bungee loops that run from the backplate to the front chest D-rings. The lower cylinder clip attaches to D-rings mounted on the waist belt or 'rails' on a butt plate.

Sidemount divers who conduct penetration diving in confined overhead environments (wreck diving or cave diving) will generally prefer a soft fabric backplate,[19] or webbing harness only, owing to the risk of a solid backplate becoming stuck in a small restriction.

An example of a commercial backplate and wing harness adapter, including integrated butt plate and attachment points for bungee loops, is the OMS Profile.[20]

Specialised and hybrid harnesses

Specialised sidemount harnesses are available.[21] Some of these are designed specifically for sidemounting only, but others are 'hybrid' designs, enabling the diver to swap between sidemount and back-mounted cylinders, as needed.[8]

Examples of dedicated sidemount rigs:

  • Hollis SMS50 [22]
  • Razor 2 [23]
  • DiveRite Nomad LT [24]
  • XDeep Stealth 2.0 [25]
  • Golem Gear A2 and S [6]
  • UTD 'Z-system' [26]

Examples of hybrid sidemount rigs:

  • Hollis SMS100 [27]
  • OMS Tesseract [28]
  • DiveRite Nomad XT or EXP
  • Custom Divers Rhino [29]
  • White Arrow S-Wing [30]

Some manufacturers now provide sidemount rigs targeted for recreational diving use. These are typically variants of existing dedicated sidemount rigs, with the low pressure inflator (LPI) mounted at the top of the BCD (rather than at the bottom corner) for an 'over the shoulder' configuration more familiar to diver's transitioning to sidemount from a traditional BCD.

Examples of dedicated recreational sidemount rigs:

  • Hollis SMS50 'Sport'[31]
  • DiveRite Nomad LT 'Blue Water'[32]


  • Hybrid (sidemount/backmount) harness. Front view
    Hybrid (sidemount/backmount) harness. Front view
  • Hybrid (sidemount/backmount) harness. Back view
    Hybrid (sidemount/backmount) harness. Back view
  • Adapted Wing sidemount BCD (32lb donut wing/OMS Profile) with soft backplate (Oxycheq Travel-Lite).
    Adapted Wing sidemount BCD (32lb donut wing/OMS Profile) with soft backplate (Oxycheq Travel-Lite).
  • Adapted Wing Sidemount BCD (rear view) with OMS Profile sidemount-adapter in on a 32lb single-tank donut wing.
    Adapted Wing Sidemount BCD (rear view) with OMS Profile sidemount-adapter in on a 32lb single-tank donut wing.

Minimalist webbing harness

Minimalist sidemount harness showing webbing, sliders and D-rings, buoyancy compensator, integrated weight holders and cylinder

A webbing harness with shoulder straps, waist belt and crotch strap, supporting a variety of sliders and D-rings for attachment of cylinders and accessories, with or without integrated weighting or separate weight belts, and with or without a back mounted buoyancy compensator, which may be attached to the harness, or directly to the diver. Cylinders are usually attached to a shoulder or chest D-ring and waist belt D-ring on each side. Additional accessories may include canister lights and clip-on pockets for small equipment. This style of harness may be off the shelf from an original equipment manufacturer or retailer,[33] or home made, as most of the parts are freely available or relatively simple to make.

Belt style 'Sump' harness

In the UK, cave diving was an additional skill learned by cavers to explore flooded parts of a cave system, rather than divers choosing to explore caves. The early equipment was little more than cylinders fitted with belt loops and slid onto the standard caver's belay or battery belt along with any extra weights needed to achieve neutral buoyancy, and a caver's belt mounted battery pack.[34] This simple sidemount configuration was particularly low profile and suited to small cylinders, and worked well for low visibility, usually fairly shallow dives, which were often more of a crawl or wriggle though tight confines than a swim.

As penetration distances into caves increased, the basic belt was replaced by a more sturdy harness with shoulder straps and padding on the waist band to distribute the load more comfortably.

A disadvantage of this arrangement is that the cylinders and lead weights must be fitted to the harness before it is put on. This usually required the diver to lie down to fit the harness, and if the cylinders were large, to be assisted to a standing position.

  • Belt loop on cylinder for sidemounting in the British cave diving style
    Belt loop on cylinder for sidemounting in the British cave diving style
  • Diving cylinders set up for British cave diving sidemounting
    Diving cylinders set up for British cave diving sidemounting
  • The original belt style British sidemount harness, with cylinders, weights and battery canister mounted.
    The original belt style British sidemount harness, with cylinders, weights and battery canister mounted.
  • A diver putting on his belt style sidemount harness. Getting up afterwards often required assistance.
    A diver putting on his belt style sidemount harness. Getting up afterwards often required assistance.
  • A diving cylinder ready for use on a British cave diving sidemount harness.
    A diving cylinder ready for use on a British cave diving sidemount harness.
  • Back view of the modified British sidemount harness.
    Back view of the modified British sidemount harness.
  • Front view of the modified British sidemount harness.
    Front view of the modified British sidemount harness.
  • Front view of the modified British sidemount harness with cylinders.
    Front view of the modified British sidemount harness with cylinders.
  • British cave diving style sidemounting harness, side view, with cylinders, weights and battery pack
    British cave diving style sidemounting harness, side view, with cylinders, weights and battery pack
  • British cave diving style sidemounting harness, side view, with cylinders, weights and battery pack
    British cave diving style sidemounting harness, side view, with cylinders, weights and battery pack
  • Helmet used for British style cave diving.
    Helmet used for British style cave diving.
  • Simplified British cave diving sidemount harness, front view.
    Simplified British cave diving sidemount harness, front view.
  • Simplified British cave diving sidemount harness, back view.
    Simplified British cave diving sidemount harness, back view.
  • Simplified British cave diving sidemount harness, side view.
    Simplified British cave diving sidemount harness, side view.

Equipment

Cylinders

Cylinder
Cylinders of varying sizes and materials can be used for sidemount diving. The optimum choice of cylinder will be determined by the water conditions and/or choice of exposure protection used.
Regulator set
Each primary sidemount cylinder requires a regulator 1st stage, a regulator second stage and a submersible pressure gauge (SPG). The left hand cylinder will also include a low-pressure inflator (LPI) for BCD inflation. If a drysuit is used, the drysuit inflator will be attached to the right hand cylinder. The most common [35] regulator configuration mimicks hogarthian[36] regulator set-up, with a long (5-7 foot) hose on the right cylinder and a short hose on the left cylinder, where the regulator is contained in a bungee necklace. However, some sidemount divers prefer an opposite configuration, two long hoses or two short hoses.
Cylinder straps
Sidemount cylinders are secured to the diver's butt-plate or rear harness D-rings via a cam-band or worm clamp to which a bolt-snap is attached via cord. The placement of the cam-band/worm clamp along the cylinder length is determined by characteristics needed to ensure cylinder trim in line with the diver's torso. The upper cylinder may be secured directly via the bungee strap, or by using a choker into a ring-bungee configuration.
Choker (#1)
A bolt-snap secured around the cylinder neck via a short cord loop that provides additional cylinder security and stability when conducting water entries with the sidemount cylinders in place [8].
Choker (#2)
A small strap around the neck of a sidemount cylinder used to pull the bolt-snap closer to the cylinder neck. Primarily used in conjunction with the DiveRite 'Ring Bungee' mounting method; this has the effect of constraining the top of the cylinder to lie closer to the shoulder of the diver for a lower profile.[37] [38] The choker is passed through the jaw of the snap and tightened, then the clip is clipped to the bungee which is clipped to the shoulder D-ring, allowing the clip to slide along the bungee.

Harness

Bungees
The use of bungees for cylinder attachment and trim is a quintessential identifier of sidemount configuration. The bungee is attached to the upper harness/BCD and routes under the diver's armpits to the shoulder D-ring area. Appropriately sized bungees ensure that the sidemount cylinders remain in trim with the diver's side torso with the valves under the armpits. The cylinder/s should neither rise above, or drop below, the diver when they are in flat, horizontal trim position. Bungees are typically wrapped around the cylinder valve handle and/or cylinder neck, to secure the cylinder whilst retaining flexibility to maneuver the cylinders into a forward position.
Double bungee
Some configurations use two lengths of bungee, typically attached to the rear of the harness/BCD via stainless steel quick-links. They may attach via dedicated D-rings on the diver's BCD or a 'daisy chain' length of looped nylon webbing that permits easy adjustment of bungee length/fit.
Continuous Bungee
Other configurations make use of a single length of bungee cord, routed from one shoulder D-ring to the other, via the rear of the diver.
Ring Bungee
First introduced commercially by DiveRite, the 'Ring Bungee' introduces a metal ring along the bungee length (in the armpit area). This permits the use of a choker to connect tanks to the ring, making bungee wrapping of the cylinder valve/neck unnecessary.

Buoyancy compensator

BAT wing configuration
Captive wing arrangements

Accessories

Cutting devices
Sidemount divers, particularly those operating in overhead environments will carry two or more cutting devices. These should be stowed where they can be easily accessed, even when in a tight passage. Popular stowage locations include; a sheath mounted on the harness or lower arm. Redundant/back-up devices may be carried in a pocket[8]. Short bladed (often titanium) knives, trauma shears or emergency line cutters (for instance, the Eezycut Trilobite[39] ) are the most popular selections for primary and back-up cutting tools.
Lights
Sidemount divers who enter overhead environments will typically carry a primary torch, often of umbilical/canister design, along with one or two back-up torches. Specific sidemount umbilical/canister torches are now sold, with a 90 degree junction for the umbilical which permits them to be mounted on the butt-plate or upper-rear crotch strap. Back-up torches are typically a robust LED design, with a battery/burn life indicated to be 2-3x that of the planned dive duration.
Reels and spools
Sidemount divers will typically carry one or more reels/spools. In open-water these may be used for deployment of delayed surface marker buoys (DSMB). In overhead environments, these will include a primary guideline and safety/jump spools - in like with cave or technical wreck diving protocols. These are typically attached to the diver on rear D-rings, normally on the butt-plate or rear waist strap, to prevent them dangling below the diver.
Line arrows and markers
Sidemount divers in overhead environments will carry a selection of directional (arrows) and non-directional (cookies) line markers. The use of Referencing Exit Markers (REM)[40] is also becoming popular with sidemount divers.
Helmet
Helmets are particularly popular with sidemount divers, as they provide a convenient mounting point for primary and/or back-up lights. The primary function of the helmet remains to provide head protection in overhead environments. Sidemount configuration can mean that the more typical method of mounting back-up lights below the diver's shoulder D-rings becomes less favorable. This area is more heavily loaded with bungee and deco stage attachments, reducing access to back-up lights stowed from the D-ring. Mounting primary lights on the helmet can be advantageous as it frees up the hands in very confined spaces and/or when heavily task-loaded with other equipment. The draw-backs to helmet mounted lights are that it can increase the risk of snagging the helmet on obstructions and an increased potential to inadvertently dazzling dive buddies.[8] Sidemount divers may choose to make their own helmet by adapting an existing climbing, kayaking or skate-boarding helmet. Off-the-shelf cave/sidemount diving helmets are also sold by companies like Light Monkey[41]
  • Home constructed sidemount helmet with GoPro video camera and back-up/video lights attached.
    Home constructed sidemount helmet with GoPro video camera and back-up/video lights attached.
  • Sidemount helmet with bungee strap
    Sidemount helmet with bungee strap
  • Technical diver with sidemount helmet, pre-dive.
    Technical diver with sidemount helmet, pre-dive.
Pocket
A pocket is useful for carrying small accessories and spares. A small nylon pouch which clips,via double-ended bolt-snap/s onto the rear/butt D-rings has the advantages of streamlining; while permitting easy access to the contents by removing/replacing the pouch as necessary.[8]

Training

Level 1: "Recreational (Rec or Basic Sidemount)"

Basic sidemount training is offered by most agencies, and aims to develop initial equipment familiarity and operation. At this level, students are taught to adjust, fit and operate the sidemount rig, whilst diving with one or two cylinders maximum.[42][35]

These training courses then develop core diving skills that are specifically relevant to sidemount – namely: trim, buoyancy, alternative propulsion techniques and cylinder handling in the water. Many basic courses also teach supplementary diving skills, such as DSMB deployment and variations on open water skills, such as inverted (upside-down) fining and inverted mask-clearing. Knowledge development covers topics such as: gas management, dive planning and equipment considerations/options.

Level 2: "Technical (Tec or Advanced Sidemount)"

Technical, or advanced, sidemount courses develop basic sidemount skills with a focus on technical diving activities. A higher level of equipment proficiency and diving skill is required, as additional stage/deco cylinders will be added to the rig, enabling mixed-gas and accelerated decompression procedures to be conducted. Technical sidemount courses often develop utilisation of the sidemount rig for increasingly demanding penetration skills – teaching students how to manipulate cylinders in order to pass through restrictions.[13]

Some agencies/instructors also provide environment specific sidemount courses at this level, focusing on sidemount diving within the cave or wreck overhead environments. These courses might incorporate the respective knowledge, skills and procedures from the cave or wreck syllabus, but adapted and focused only on performance in sidemount configuration.

Procedures

One of the advantages of the sidemount system is the easy access to cylinder valves, and the protected position they occupy in comparison with most back mount systems, where the valves are relatively vulnerable to bumping against an overhead and being "rolled off" (closed by rubbing against the overhead).

The standard arrangement for sidemount is that all cylinders are independent, and each is provided with a single demand valve, an SPG, and on one or two, a low pressure inflator hose for buoyancy compensator and, if used, the drysuit. This implies that if gas is shared in an emergency, the recipient will be breathing from a different cylinder to the donor, unlike the more usual arrangement with backmount, where both divers breathe off the same set.

In the case of recreational sidemount, with only one cylinder, the regulator would have an octopus demand valve for air sharing and the procedures would revert to much the same as for a single back mount cylinder.

Gas management

The sidemount diver typically operates two independent tanks for 'bottom gas' during their dive. Unlike diving with back-mounted double cylinders and an isolation manifold, the use of independent cylinders requires additional gas management skills. The sidemount diver has to swap regulators at pre-defined intervals to ensure that the use of gas is balanced from both cylinders - thus ensuring good balance and trim in the water, whilst preserving a sufficient supply of air for emergency sharing.[43]

As of 2012, the only sidemount system offering a manifold system is the UTD ‘Z-Manifold'. This equipment provides a link between cylinders and dispenses with the need to swap regulators and balance tanks. In all other instances, the sidemount diver will follow a gas management strategy, which enable roughly equal consumption of gas from both sidemount cylinders and retains a necessary minimum reserve in both cylinders to enable an air-sharing exit/ascent from the dive (1/3 preserved total cylinder volume in each tank minimum).

Rule of thirds and reserves

Most technical and overhead-environment divers will maintain the rule of thirds as the least conservative option when diving sidemount. Because air-sharing will always remain a possibility, it is essential that both cylinders maintain an independent reserve of, at least, 1/3 capacity.

It is not sufficient to drain one cylinder, retaining your reserve in the other.

Balancing cylinders - regulator switching
To maintain balance (approximately matched buoyancy characteristics) between cylinders, there is a requirement for switching regulators during the dive.
Swapping 1/6
One method of maintaining cylinder balance is to swap regulators for every 1/6 cylinder gas consumption. This would mean each regulator was breathed from twice, before reaching the gas turn-point (2/3) and a further two switches on each regulator until the reserve (1/3) was reached.[44]
Swapping 1/3
An alternative method (simpler, but less refined cylinder balancing) would be to switch regulators with every 1/3 gas consumed (on each cylinder). This would mean each regulator was used once, before reaching the gas turn-point (2/3) and once more, per regulator, before reaching reserve level (1/3).
Draining a tank to reserve, then switching
It is not possible to breath from a single cylinder until the turn-point, and then switching. This would leave insufficient gas remaining in that cylinder for an air-sharing exit or ascent – as the diver would only have 1/3 of a cylinder, not 1/3 total supply for that exit.

Regular regulator switching also helps ensure that neither regulator becomes unworkable – an especially prudent measure when sidemount diving through restrictions in high silt and mud conditions.

Critical skills

The following represents a summary of the critical skills taught by a spectrum of agencies at various sidemount diving levels:[45][46]

Level 1: "Recreational (Rec or Basic Sidemount)"

  • Equipment configuration and assembly
  • Pre-dive safety checks
  • Attaching tanks on land and at the surface (shallow and deep water)
  • Descent procedures
  • Trim and buoyancy
  • Propulsion techniques – frog kick, modified flutter kick, back kick, helicopter turn
  • Gas planning and management (independent cylinders)
  • Regulator switching
  • Air sharing - donor and receiver
  • Tank positioning and adjustment for continual good trim
  • Removal of single tank while swimming
  • Removal of two tanks while swimming
  • Inverted and/or vertical mask clearing
  • DSMB deployment ascent procedures

Level 2: "Technical (Tec or Advanced Sidemount)"

  • Equipment configuration and assembly
  • Stage bottle configuration and assembly
  • Water entry procedures
  • Descent procedures
  • Trim and buoyancy
  • Propulsion techniques - frog kick, modified frog and flutter kick, back kick, helicopter turn, finger walking, pull and glide
  • Sidemount diving mobility – inverted propulsion, rolls, loops etc
  • Gas planning and management, including decompression gasses.
  • Team drills and development
  • Guideline/penetration contingency drills
  • Sidemount regulator shut-downs
  • Feather breathing from a shut-down free-flowing regulator [13] (Manipulating the valve to temporarily supply air from a shut-down cylinder as you breath).
  • Swapping regulators between cylinders underwater
  • In-water stage bottle attachment, removal and replacement
  • Sidemount decompression procedures
  • Practice of all sidemount skills (Level 1 & Level 2) within specific over-head environment (cave/wreck)

Compatibility in mixed configuration team diving

The basic sidemount configuration requires different techniques for sharing gas, compared to the isolation manifolded twins back mount configuration.[47] This means that a single set of standardised safety procedures is not possible while diving with team members using back mounted tanks.

The UTD Z-system provides an approach to emulate back mounted Hogarthian configuration by quick-connecting two primary gas supply sidemount cylinders to a manifold block mounted behind the shoulders on the Z-system harness, from which long hose primary and necklace secondary demand valves are supplied, reducing the demand valve arrangement to a functional approximation of the standard Hogarthian configuration at the expense of additional complexity of components.[47][48]

The added failure points may not be necessary when using more than one bottle at the time.[clarification needed] Additional stage cylinders are side mounted with independent regulators.

  • Sidemount diver in fairly tight space
    Sidemount diver in fairly tight space
  • Left side view of sidemount diver in cave
    Left side view of sidemount diver in cave
  • Top view of sidemount diver
    Top view of sidemount diver
  • Sidemount diver front view. Holding reel and DSMB
    Sidemount diver front view. Holding reel and DSMB
  • Sidemount diver: detail of top of cylinder
    Sidemount diver: detail of top of cylinder
  • Sidemount diver in cave showing 2 cylinders and BC back view
    Sidemount diver in cave showing 2 cylinders and BC back view
  • Sidemount diver operating cylinder valve
    Sidemount diver operating cylinder valve
  • Sidemount diver near surface
    Sidemount diver near surface

References

  1. ^ "PADI launches new Tec Sidemount Diver course". Diverwire. 5 March 2012. Retrieved 18 August 2012.
  2. ^ Hires, Lamar (Summer 2010). "Sidemount – Not Just For Cave Divers Anymore". Alert Diver Magazine. Retrieved 18 August 2012.
  3. ^ "PADI puts full weight behind sidemount diving". Diver Magazine. 6 June 2010. Retrieved 18 August 2012.
  4. ^ "Holy Sidemount!". X-Ray Magazine. 25 April 2010. Retrieved 18 August 2012.
  5. ^ Liddiard, John (June 2012). "Stage or Sidemount - What's the Difference?". Diver Magazine. Retrieved 18 August 2012.
  6. ^ a b "Golem Gear, Inc. - Armadillo Sidemount Exploration Harness A2". Golemgear.com. Retrieved 18 August 2012.
  7. ^ Bowen, Curt. "CCR Sidemount - Stage Configuration for Exploration". Advanced Diver Magazine. Retrieved 18 August 2012.
  8. ^ a b c d e f g h i j k Kakuk, Brian; Heinerth, Jill (2010). Side Mount Profiles. High Springs, FL: Heinerth Productions. ISBN 97809798954. {{cite book}}: Check |isbn= value: length (help)
  9. ^ Davis, Andy. "Sidemount Diving Course Notes, Chapter 2". Sidemount Diving Course Notes. Scuba Tech Philippines. Retrieved 18 August 2012.
  10. ^ a b Bogaerts, Steve (2010). "Why Sidemount". GUE Conference Presentation. Retrieved 18 August 2012.
  11. ^ "Side-Mount Diving". Sport Diver Magazine. 29 June 2010. Retrieved 18 August 2012.
  12. ^ "Sidemount Workshop – a matter of comfort". X-Ray Magazine. 15 January 2010. Retrieved 18 August 2012.
  13. ^ a b c "Tec Sidemount Instructor Guide". Professional Association of Diving Instructors. June 2012. {{cite web}}: |access-date= requires |url= (help); Missing or empty |url= (help)
  14. ^ Davis, Andy. "Sidemount Diving Course Notes". Sidemount Diving Techniques. Scuba Tech Philippines. Retrieved 18 August 2012.
  15. ^ Ryall, Dave. "Cave Diving British Style". Sidemount Diving Techniques. Cave Diving Group (CDG). Retrieved 18 August 2012.
  16. ^ Martin, Steve (January 2012). "Sidemount Diving - The Next 'Big Thing' in British Diving". Sport Diver Magazine. {{cite web}}: |access-date= requires |url= (help); Missing or empty |url= (help); Unknown parameter |http://www.sidemountscubadiving.com/LinkClick.aspx?fileticket= ignored (help)
  17. ^ Loflin, Jeff. "Technical Scuba - Sidemount Diving".
  18. ^ Neto, Rob (4 March 2012). "Choosing A Sidemount Rig". Chipolata Divers. Retrieved 19 August 2012.
  19. ^ "Oxycheq Ultra Lite Backplate". Oxycheq. 18 August 2012. Retrieved 18 August 2012.
  20. ^ "OMS Profile Sidemount System". Big Blue Technical Diving News and Events. 25 November 2009. Retrieved 18 August 2012.
  21. ^ "Armadillo sidemount manual". Advanced diver magazine. Retrieved 18 August 2012.
  22. ^ Cooper, Tony (23 April 2012). "Underwater Explorers: The Hollis SMS 50 review 2012". Underwaterexplorers.blogspot.com. Retrieved 18 August 2012.
  23. ^ "Go Side Mount Shop. Manual for the Razor Harness 2". Shop.gosidemount.com. Retrieved 18 August 2012.
  24. ^ "Sidemount diving, Nomad sidemount system, sidemount training, Dive Rite scuba". Diverite.com. Retrieved 18 August 2012.
  25. ^ "ProTec Dive Center Sidemount Diving - Sidemount Harness". Protecsidemount.com. Retrieved 18 August 2012.
  26. ^ "Z-Harness". Retrieved 2 November 2012.
  27. ^ "SMS100 Sidemount Harness Manual" (PDF). Hollis Gear. Retrieved 18 August 2012.
  28. ^ "Seaduction - Field Test: OMS Sidemount Systems". Seaduction.com. 5 March 2011. Retrieved 18 August 2012.
  29. ^ Pat (1 April 2012). "Custom Divers Rhino revealed". British Diver. Retrieved 18 August 2012.
  30. ^ "HLBdive White Arrow Sidemount Wing". hlbdive.com. February 2013. Retrieved 6 February 2013.
  31. ^ DiverWire. "HOLLIS to Unveil new SMS50 SPORT Sidemount System at DEMA Show". DiverWire. Retrieved 25 February 2013.
  32. ^ DiverWire. "Dive Rite Releases Sidemount BCD For Ocean Diving". Diverwire. Retrieved 25 February 2013.
  33. ^ Bogaerts, Steve (31 August 2011). "Go Side Mount". Go Cavern Diving. Retrieved 18 August 2012.
  34. ^ Price, Duncan (4 April 2005). "Rebreather". Sump4.com. Retrieved 18 August 2012.
  35. ^ a b "Sidemount Instructor Guide". Professional Association of Diving Instructors. March 2012. {{cite web}}: |access-date= requires |url= (help); Missing or empty |url= (help)
  36. ^ Jablonski, Jarrod (21 March 1997). "Hogarthian Gear Configuration". originally posted to rec.scuba by Carl Heinzl on 21 March 1997. Retrieved 25 February 2013.
  37. ^ Hires, Lamar. "Sidemount Scuba Diving Nomad Tank Chokers: Dive Rite". DiveRite84. Retrieved 26 February 2013.
  38. ^ Hires, Lamar. "New Nomad Tank Attachment". DiveRite. Retrieved 26 February 2013.
  39. ^ Eezycut. "Eezycut Trilobite ECT". Eezycut. Retrieved 25 February 2013.
  40. ^ Philips, Bil. "Cave Explorer and Cave Instructor Bil Phillips introduces the REM". www.gosidemount.com. Retrieved 25 February 2013.
  41. ^ DiveRightInScuba. "Light Monkey Cave Diving Helmet". DiveRightInScuba. Retrieved 25 February 2013.
  42. ^ Davis, Andy. "Sidemount Diving Course Notes, Chapter 5". Sidemount Diving Course Notes. Scuba Tech Philippines. Retrieved 18 August 2012.
  43. ^ Davis, Andy. "Sidemount Diving Course Notes, Chapter 8". Sidemount Diving Course Notes. Scuba Tech Philippines. Retrieved 18 August 2012.
  44. ^ Neto, Rob (4 March 2012). "Sidemount Gas Management". Chipolata Divers. Retrieved 19 August 2012.
  45. ^ Davis, Andy. "Sidemount Diving Course Notes, Chapter 10". Sidemount Diving Course Notes. Scuba Tech Philippines. Retrieved 18 August 2012.
  46. ^ Rockwood, Kelly (27 October 2011). "Testing the new PADI Sidemount Diver Course". PADI TecRec Blog. Retrieved 19 August 2012.
  47. ^ a b "Z-Side-Mount System". UTD International. 5 April 2012. Retrieved 18 August 2012.
  48. ^ Jablonski, Jarrod. "The Hogarthian Gear Configuration". Jeff Bentley. Retrieved 13 October 2008.

Further reading

  1. Heinerth, Jill (2012). Side Mount Profiles. Heinerth Productions Inc. ISBN 978-0979878954.

External links

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