Submarine Rescue Diving Recompression System
The Submarine Rescue Diving Recompression System (SRDRS) is a United States Navy capability designed to perform rescue operations on submerged, disabled submarines belonging to the U.S. Navy or allied forces, enabling the safe extraction and pressurized transfer of up to 16 personnel per mission from depths of up to 2,000 feet (610 meters) directly to a surface decompression facility without requiring survivors to undergo immediate decompression on the submarine.[1] Developed in response to the limitations of earlier rescue technologies exposed by incidents such as the 1963 loss of USS Thresher (SSN-593), the SRDRS program was initiated in 1998 as a replacement for the retired Deep Submergence Rescue Vehicles (DSRVs), which were decommissioned in 2008 after proving inadequate for modern submarine depths and operational needs.[2][1] The system integrates commercial off-the-shelf components adapted for naval use, built by OceanWorks International in Vancouver, Canada, and achieved initial operational capability in 2008, with the Submarine Decompression System achieving initial operational capability in 2019.[2][1] At its core, SRDRS comprises three primary subsystems: the Assessment/Underwater Work System (AUWS), a tethered remotely operated vehicle (ROV) equipped with tools for submarine inspection, hatch preparation, and underwater tasks up to 2,000 feet; the Submarine Rescue Chamber System (SRS-RCS), featuring a Pressurized Rescue Module (PRM) that mates directly to the submarine's escape trunk for survivor transfer under pressure; and the Submarine Decompression System (SRS-SDS), which provides hyperbaric chambers and life support for controlled decompression using advanced dive tables, eliminating the risks associated with rapid ascent.[1] The PRM measures 49 feet (15 meters) in length and 8 feet (2.4 meters) in beam, accommodates two tenders and 16 passengers, and can be rapidly deployed via truck, aircraft, or ship to a vessel of opportunity without requiring specialized mother submarines, unlike predecessor systems such as the McCann Rescue Chamber, which was limited to 850 feet.[1][2] Operated by the Undersea Rescue Command at Naval Air Station North Island, San Diego, the government-owned, contractor-operated SRDRS enhances international interoperability, as demonstrated in exercises like NATO's Bold Monarch in 2011, though its single-unit configuration poses challenges to redundancy and sustained training amid budgetary constraints.[1][2] By 2017, the system had been installed aboard vessels like the Military Sealift Command-chartered HOS Dominator, underscoring its mobility and readiness for global deployment in crisis scenarios.[3] In April 2025, JFD North America integrated an advanced Integrated Cross Deck Communication System into SRDRS to improve communication and safety during operations.[4]Overview
Purpose and Role
The Submarine Rescue Diving Recompression System (SRDRS) is a portable, integrated system developed by the U.S. Navy that combines remotely operated vehicles, pressurized rescue modules, and hyperbaric chambers to facilitate the rescue of personnel from disabled submarines at depths up to 610 meters.[1] Its primary purpose is to enable the safe evacuation and treatment of submariners trapped underwater, addressing the critical challenges of deep-sea rescue operations where rapid response is essential to survival.[2] By providing a means for transfer-under-pressure, the SRDRS minimizes the risk of decompression sickness (DCS), also known as the bends, which can occur during rapid ascent from pressurized environments.[5] The development of SRDRS was driven by historical submarine incidents, notably the 1963 loss of USS Thresher, which sank during deep-diving trials off the New England coast, resulting in the deaths of all 129 aboard and highlighting the need for advanced rescue capabilities.[1] This tragedy led to the creation of the earlier Deep Submergence Rescue Vehicles (DSRVs), which were retired in 2008 due to obsolescence and maintenance challenges, prompting the introduction of SRDRS as their successor to maintain operational readiness. The system entered service that year, with initial operational capability for core components in 2008 and full deployment, including the Submarine Decompression System, achieved in 2019.[2][1] In addition to its role in U.S. Navy operations, SRDRS supports international cooperation by performing rescues on disabled submarines from foreign navies, with its design ensuring compatibility with allied vessels and systems.[1] This interoperability has been demonstrated in joint exercises, such as NATO drills where the system mated with non-U.S. submarines, underscoring its strategic importance in global maritime security.[6]Key Capabilities
The Submarine Rescue Diving Recompression System (SRDRS) is engineered to conduct rescue operations at depths up to 2,000 feet (610 meters), enabling intervention on disabled submarines in deep water scenarios.[7] The Pressurized Rescue Module (PRM) within the system can transport up to 16 rescued personnel per sortie, along with two operators, allowing for the extraction of a full 155-person submarine crew in approximately 10 trips under optimal conditions.[1][8] SRDRS supports rapid global deployment, achieving readiness for mating with a distressed submarine within 72 hours via airlift on C-5 or C-17 aircraft, overland trucking, or sealift to a vessel of opportunity (VoO).[6][9] This flexibility leverages over 2,000 potential VoOs worldwide, ensuring operational reach without reliance on specialized rescue vessels.[10] The system accommodates mating with submarine escape hatches inclined up to 45 degrees while maintaining the PRM in a horizontal orientation, and it is compatible with most international submarine designs, including classes such as Type 209, Kilo, and Collins.[5][7] For initial assessment, remotely operated vehicles (ROVs) can survey the site and clear fouled hatches to facilitate docking.[7] SRDRS integrates recompression capabilities through its Submarine Decompression System, which includes two chambers supporting up to 64 personnel total and enables hyperbaric treatment during transfer under pressure (TUP) from the submarine to surface support, mitigating decompression sickness risks en route.[7][10] This pressurized pathway allows continuous medical intervention without requiring immediate surfacing to atmospheric conditions.[1]History
Development and Design Origins
The development of the Submarine Rescue Diving Recompression System (SRDRS) was initiated in 1998 by the U.S. Navy as a replacement program for the aging Deep Submergence Rescue Vehicles (DSRVs), which had been planned for retirement amid evolving post-Cold War submarine operations. This effort was motivated by historical lessons from major submarine losses, including the USS Thresher (SSN-593) in 1963 and USS Scorpion (SSN-589) in 1968, which underscored the need for advanced rescue capabilities to address deep-water casualties. The program aimed to restore and modernize the Navy's ability to conduct rapid, global submarine rescues following the decommissioning of dedicated support vessels. OceanWorks International, based in Vancouver, Canada, served as the primary builder for key SRDRS elements, drawing partial design influences from the Royal Australian Navy's Remora system, particularly its pressurized transfer technology. Key milestones included contract awards in the early 2000s, such as the 2000 award for the Pressurized Rescue Module development, with full system delivery to the fleet achieved in 2008. The Submarine Decompression System component reached initial operational capability (IOC) in 2019, marking a significant step toward full system integration. Design goals emphasized the use of commercial-off-the-shelf (COTS) components to enhance cost efficiency, maintainability, and rapid deployment, while ensuring portability via air, sea, or land transport to mitigate vulnerabilities exposed by the decommissioning of support ships like USS Pigeon (ASR-21) in 1992. Program oversight and budgeting were managed by the U.S. Navy's Undersea Rescue Command (URC), which coordinated acquisition, testing, and integration under Naval Sea Systems Command guidance to align with broader undersea warfare priorities.Operational Deployments
Following its delivery to the U.S. Navy in 2008, the Submarine Rescue Diving Recompression System (SRDRS) underwent initial full-system tests between 2008 and 2010 to verify integration and operational readiness, culminating in the replacement of legacy systems like the Mystic-class Deep Submergence Rescue Vehicle (DSRV).[2] The system is maintained by the Undersea Rescue Command at Naval Air Station North Island, San Diego, California, serving as the central hub for mobilization and preparation for global deployment. In 2017, Undersea Rescue Command (URC) installed the SRDRS aboard the Military Sealift Command-chartered merchant vessel M/V HOS Dominator to enable forward deployment and rapid response capabilities from a vessel of opportunity (VoO).[3] This installation addressed key operational challenges, including the logistics of converting commercial VoOs into suitable platforms and ensuring swift global transport via truck, aircraft, or ship to reach distressed submarines within critical timelines.[5] The SRDRS has participated in numerous exercises demonstrating its integration into naval operations, including international drills such as NATO's Dynamic Monarch in 2017, where URC teams tested rescue procedures alongside allies like the United Kingdom.[11] It also featured in the Pacific Reach 2019 exercise off Hawaii, honing regional submarine rescue skills with partners including Australia through simulated missions involving search, assessment, and transfer under pressure.[12] These exercises, akin to multinational events like Black Carillon, underscore the system's interoperability with allied forces for coordinated responses.[13] As of 2025, the SRDRS remains the primary U.S. Navy asset for submarine rescue, supporting worldwide operations for both American and allied vessels while undergoing ongoing upgrades, such as enhanced medical monitoring and communication integrations to improve portability and safety.[14][15]System Components
Assessment and Underwater Work System
The Assessment and Underwater Work System (AUWS) serves as the initial phase of the Submarine Rescue Diving Recompression System (SRDRS), enabling rapid evaluation and preparation of a disabled submarine (DISSUB) for subsequent rescue operations. It comprises remotely operated vehicles (ROVs), and associated support equipment, all designed for deployment from a vessel of opportunity (VOO) to depths of up to 2,000 feet (610 meters) of seawater. This system facilitates hull inspection, hatch clearance, and debris removal without exposing personnel to hyperbaric risks, ensuring safe conditions for pressurized rescue module (PRM) mating.[1][5] The core unmanned component of the AUWS is the ROV, which performs critical pre-rescue tasks such as scanning the DISSUB's hull for structural integrity, verifying escape hatch accessibility, and removing obstructions like debris or entangled lines. Equipped with high-resolution video cameras, sonar imaging, and manipulator arms fitted with tools for cutting, grinding, and other operations, the ROV provides real-time data feeds to surface operators for informed decision-making. Its tether, extending up to 2,000 feet, allows controlled navigation in currents up to 2.5 knots and sea states up to 4, while maintaining power and communication via an umbilical. Additionally, the ROV can interface briefly with the PRM to support transfer preparations by confirming hatch alignment.[5][1][16] Deployment and recovery of the ROV components rely on integrated launch systems, including flyaway side-looking sonar for initial DISSUB localization, umbilical winches for tether management, and a deck-mounted A-frame crane on the VOO for handling up to 45,000-pound loads in moderate sea conditions. These elements are containerized for rapid air or sea transport, achieving operational readiness within 24-72 hours of alert, and provide sonar and video data to assess submarine stability—such as tilt angles up to 45 degrees—and hatch usability before PRM attachment. This preparatory role minimizes risks in time-sensitive scenarios, enhancing overall rescue efficiency. In April 2025, an Integrated Cross Deck Communication (ICDC) System was integrated into SRDRS to enhance communication across the deck and to submersibles using advanced digital audio routing and redundant fiber-optic technology.[5][17][18][4]Pressurized Rescue Module System
The Pressurized Rescue Module (PRM), designated PRM-1 Falcon, serves as the primary rescue vehicle in the Submarine Rescue Diving Recompression System (SRDRS), enabling the transfer of personnel from a disabled submarine (DISSUB) to a surface vessel while maintaining ambient pressure to avoid decompression sickness.[1] This tethered, remotely operated submersible is designed for rapid deployment from a vessel of opportunity (VOO), with a maximum operational depth of 2,000 feet (610 meters).[1] Measuring 49 feet (15 meters) in length and 8 feet (2.4 meters) in beam, the PRM provides a stable platform for evacuation, accommodating up to 16 rescuees and 2 tenders (operators) per sortie in a seated configuration.[1][19] Internally, the PRM maintains a pressurized environment equivalent to the DISSUB's depth, equipped with emergency breathing systems (EBS) including masks supplied by high-pressure air and 90% oxygen for decompression support, CO2 scrubbers, and provisions for air breaks to mitigate oxygen toxicity.[20] Medical monitoring is facilitated by the tenders, who can summon additional medical personnel via lockout if needed for injured rescuees.[20] The module's life support systems support sortie durations of approximately 6 hours, with surface replenishment enabling multiple back-to-back operations for evacuating larger crews.[20] The PRM mates to the DISSUB via a detachable transfer skirt, a bell-shaped structure that seals to the escape hatch and accommodates pitch and roll angles up to ±45 degrees through a rotating hydraulic mechanism with clamps for secure attachment.[21][22] This universal mating interface is compatible with standard submarine escape hatches measuring 25 to 30 inches in diameter.[5] Following an initial assessment by a remotely operated vehicle to confirm hatch accessibility, the transfer skirt is positioned, pumped down for pressure equalization, and clamped in place to facilitate personnel ingress.[23] Deployment and recovery of the PRM are managed by the Launch and Recovery System (LARS), which includes a deck-mounted cradle for securing the module, an umbilical winch supplying power, communications, and control signals via a 2,500-foot tether, and a dedicated control van for remote operation from the VOO's deck.[5] The entire PRM system, including support equipment, is transportable by truck, aircraft, or ship for global response within 72 hours of notification.[1]Submarine Decompression System
The Submarine Decompression System (SDS) is a surface-based hyperbaric facility within the U.S. Navy's Submarine Rescue Diving Recompression System (SRDRS), designed to provide safe, under-pressure transfer and treatment for personnel rescued from disabled submarines. It enables the decompression of up to 72 individuals simultaneously, using advanced dive tables to mitigate decompression sickness (DCS) after exposure to high pressures. The system supports hyperbaric recompression from depths up to 610 meters (2,000 feet seawater), ensuring rescued sailors receive immediate medical intervention without risking further injury from rapid pressure changes.[1][5] Central to the SDS are two 36-person Surface Decompression Chambers (SDCs), each capable of accommodating 32 rescued personnel and four tenders for multi-patient treatment. These chambers employ oxygen-accelerated decompression protocols based on U.S. Navy tables, such as those from the Thalmann Algorithm, to optimize safety and efficiency during extended recompression cycles that may last 24-48 hours. The SDCs are equipped with life support systems including oxygen delivery via the Mask-Based Breathing System 2000 (MBS 2000) for enriched breathing gas (up to 90% oxygen fraction), CO2 scrubbers using lithium hydroxide (LiOH) canisters, and integrated medical equipment for DCS monitoring and treatment, such as hyperbaric oxygen therapy.[8][5][20] Seamless under-pressure handover from the Pressurized Rescue Module is facilitated by the Hyperbaric Transfer Chamber (HTC) and Deck Transfer Lock (DTL), which connect via flexible manways to maintain chamber integrity during personnel transfer at depths like 50-60 feet seawater. These components allow for a 30-minute transfer process without decompression interruption, supporting repetitive sorties for full crew rescue. The SDS achieved Initial Operational Capability (IOC) in 2019, marking its readiness for full-spectrum recompression from 610-meter depths.[1][8][20] As portable units, the SDS components are deployable on vessels of opportunity (VOO) decks via truck, aircraft, or ship transport, requiring external power supplies (typically 440V, 60 Hz, three-phase) and compressed gas sources for operation. This modular setup ensures rapid mobilization, with the chambers and locks forming a connected hyperbaric network that can handle both ambulatory rescuees and stretcher cases in emergency scenarios.[1][5][20]Operations
Rescue Procedure
The rescue procedure for the Submarine Rescue Diving Recompression System (SRDRS) follows a structured, multi-phase sequence to evacuate personnel from a disabled submarine (DISSUB), integrating the Assessment and Underwater Work System (AUWS), Pressurized Rescue Module (PRM), and Submarine Decompression Chambers (SDCs) while maintaining pressure to prevent decompression sickness.[1] The process prioritizes rapid assessment and transfer, with the entire operation for a full crew typically estimated at 24-48 hours, depending on DISSUB depth and crew size.[20] Phase 1: Deployment to Incident SiteThe SRDRS is mobilized and transported to the incident site via truck, aircraft, or ship for global rapid response, then set up on a Vessel of Opportunity (VOO) serving as the operational platform, which must have sufficient deck strength (at least 614 lbf/ft² static load for the Launch and Recovery System area and 512 lbf/ft² overall, with dynamic loads up to 1,024 lbf/ft²) for handling equipment.[1][18] Once on site, the VOO transits to within a 500-foot radius watch circle of the DISSUB and moors securely to enable launch and recovery operations.[18] This phase emphasizes quick setup to minimize response time, with the system designed for compatibility with commercial or naval vessels in the vicinity.[1] Phase 2: AUWS/ROV Assessment of DISSUB
The AUWS, a remotely operated vehicle (ROV), is deployed to locate the DISSUB, evaluate its condition, and prepare the escape hatch by clearing debris or verifying structural integrity, operating effectively down to 2,000 feet.[1][24] Assessment confirms the DISSUB's angle is no greater than 45 degrees (pitch and roll) and internal pressure does not exceed 5 atmospheres absolute (ata) to ensure safe mating.[18][24] Equivalent Air Depth (EAD) is calculated based on DISSUB depth and internal gas composition to inform decompression planning, using the formula \mathrm{EAD} = \frac{ (D_{\mathrm{sub}} + 33) - \left( \frac{\% \mathrm{O_2}_{\mathrm{sev}} + \% \mathrm{CO_2}_{\mathrm{sev}}}{100} \right) \times 33 }{0.79} - 33 where D_{\mathrm{sub}} is the submarine depth in feet of seawater.[20] If ROV capabilities are insufficient for hatch preparation, diving suits may be used for manual interventions by a Dive Extension Team (DET).[20] Phase 3: PRM Launch, Mating to Hatch, Personnel Boarding, and Pressurized Ascent
The PRM, a tethered remotely operated vehicle, is launched from the VOO using the Launch and Recovery System (LARS) with active motion compensation, descending to the DISSUB at controlled rates (e.g., 100 feet of seawater per minute initially).[1][18] It mates to the prepared hatch with tolerance for up to ±30 degrees misalignment via a cursor frame, equalizes pressure, and allows up to 16 seated personnel, reduced for stretcher cases (e.g., to 8 seated with 3 stretchers), to board while maintaining a pressurized environment.[24][18][20] The PRM then ascends to the surface under power, with rescuees pre-breathing oxygen (e.g., 2 hours at 50 feet seawater) to mitigate decompression risks, completing a single sortie in 4.3 to 7.1 hours depending on depth.[20] Phase 4: Transfer via HTC/DTL to SDCs for Decompression
Upon surfacing, the PRM is recovered to the VOO, and rescuees are transferred under pressure through the Handling and Transfer Chamber (HTC) or Deck Transfer Lock (DTL) to the SDCs, which have a total capacity of up to 35 personnel but support oxygen treatment for up to 33 via masks.[1][20] Decompression in the SDCs follows staged protocols (e.g., oxygen breathing at initial stops like 50 feet seawater for 75 minutes), lasting 24-72 hours based on exposure depth and Equivalent Air Saturation Depth if conditions varied over time.[20] This phase ensures safe off-gassing, with attendants managing the process in modes such as single chamber for shallower depths (25-30 feet seawater) or dual chamber hold for deeper scenarios (60+ feet seawater).[20] Contingencies
The procedure accommodates inclined hatches up to 45 degrees and requires multiple PRM trips (typically 10-11 sorties for a full crew of 155), with delays between sorties (e.g., 24 hours at depths yielding EAD ≥60 feet seawater) to manage gas supplies and attendant fatigue.[24][20] In cases of power failures or equipment issues, backup systems on the VOO enable continued operations, while central nervous system oxygen toxicity during pre-breathing triggers abort protocols, including ascent at 1 foot seawater per minute and air breaks.[18][20] If SDCs are unavailable, an emergency surface interval decompression may be used, involving extended oxygen pre-breathing in the PRM before surfacing and recompression.[20]
Training and Support Requirements
The operation of the Submarine Rescue Diving Recompression System (SRDRS) requires a specialized team under the Undersea Rescue Command (URC), comprising active duty sailors, reserve personnel, and government contractors to provide 24/7 worldwide coverage for rescue missions.[25] The core operational crew for the Pressurized Rescue Module (PRM) component includes two system operators and two tenders, supported by additional roles such as divers, hyperbaric chamber operators, medical technicians, and remotely operated vehicle (ROV) pilots.[1] These personnel undergo rigorous training, including quarterly at-sea drills aboard support vessels using the SRDRS or Submarine Rescue Chamber (SRC), featuring simulated medical scenarios with manikins, moulage, and pressurized chambers to prepare for real-world contingencies.[7] Training emphasizes annual certifications and exercises, such as the Mass Casualty Exercise (MASSEVEX), to maintain proficiency in hyperbaric operations and rescue procedures.[7] URC also participates in joint international drills, including NATO-led exercises like Dynamic Monarch, Black Carillon, and Sorbet Royal, to enhance interoperability with allied navies in submarine rescue scenarios; for example, in September 2024, URC took part in Exercise Dynamic Monarch 24.[26][27] Divers and technicians receive foundational certification through the Naval Diving and Salvage Training Center (NDSTC), the U.S. Navy's primary facility for advanced diving and salvage skills.[28] Logistically, the SRDRS demands a vessel of opportunity (VOO)—a commercial or naval ship—with a minimum deck area of approximately 3,300 square feet (98 ft x 34 ft) for the temporary uplift package (TUP) configuration, including space for the PRM launch and recovery system (LARS), control van, gas racks, and umbilical winch.[18] The VOO must provide deck strength of at least 614 lbf/ft² statically for the LARS (512 lbf/ft² overall, up to 1,024 lbf/ft² dynamically), along with utilities like power generation, and cranes or handling gear compatible with the system's 224 long tons weight; vessels must maintain position-keeping within a 500-foot radius, often via dynamic positioning (ABS DPS-2 class).[18] Global prepositioning enables a 96-hour response capability, with components transportable by truck, C-5/C-17 aircraft, or ship for rapid worldwide deployment.[1][7] Maintenance of the SRDRS is overseen by URC, incorporating routine inspections, testing, repair, and refurbishment to ensure operational readiness, with integrated logistics support provided by contractors like Oceaneering for hyperbaric and ROV elements.[25][26] The system supports integration with dedicated naval vessels, such as salvage ships in the Safeguard class (e.g., USNS Safeguard), for extended operations requiring enhanced diving and recovery capabilities.[1]Specifications and Compatibility
Technical Specifications
The Pressurized Rescue Module (PRM), a core component of the Submarine Rescue Diving and Recompression System (SRDRS), measures 49 feet (15 m) in length and has a beam of 8 feet (2.4 m).[1] The Submarine Rescue System (SRS), a core component of the SRDRS, weighs approximately 183 tons when installed on a vessel of opportunity.[5] The system achieves a maximum operational depth of 2,000 feet (610 m) seawater for both the full SRDRS and its Atmospheric Diving Suits (ADS).[1] The PRM's descent and ascent rates are limited to a maximum of 100 feet per minute.[20] As a tethered vehicle, the PRM draws primary power via umbilical from the support vessel, with battery backup enabling emergency operations if the tether is severed.[29] The PRM's pressure hull is constructed from HY-100 steel, capable of withstanding pressures exceeding 600 psi at operational depths, supplemented by composite materials in non-structural elements for weight optimization.[30] Life support systems provide gas supplies sufficient for up to 16 rescuees plus two operators during submerged operations.[1]| Parameter | Specification |
|---|---|
| PRM Length | 49 ft (15 m) |
| PRM Beam | 8 ft (2.4 m) |
| SRS Weight | ~183 tons |
| Depth Rating (System/ADS) | 2,000 ft (610 m) |
| Descent/Ascent Rate | Max 100 ft/min |
| Pressure Hull Material | HY-100 steel (withstands >600 psi) |
| Capacity (with gas supply) | 16 rescuees + 2 operators |