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3-ring release system

The 3-ring release system is a mechanical safety device integral to modern skydiving harnesses and parachute rigs, designed to enable the rapid detachment of a malfunctioning main canopy from the jumper's body during freefall.^[1] It consists of three concentric stainless steel rings—a large ring fixed to the harness, a medium ring passing through the large ring, and a small ring passing through the medium ring and attached to the main canopy risers via a short piece of webbing, with the risers' locking loop passing through the small ring—linked together such that pulling a cutaway handle releases a cable that sequentially disengages the rings under load, allowing the faulty parachute to separate cleanly while the jumper deploys their reserve.^[1] This system revolutionized emergency procedures by simplifying the cutaway process compared to earlier mechanisms like the Capewell system, which required more complex multi-step actions unsuitable for sport parachuting.^[2] Invented by American skydiver and engineer Bill Booth in the mid-1970s, the 3-ring system drew inspiration from release mechanisms used in tethered balloon operations and was initially developed using off-the-shelf hardware to address the limitations of military-derived equipment in civilian skydiving.^[2] Booth, who held multiple patents for skydiving innovations, introduced the system to provide a reliable, low-friction release that could handle dynamic loads up to several thousand pounds without jamming, marking a pivotal advancement in sport parachuting safety.^[3] By the late 1970s, it had become the standard for attaching risers to harnesses in ram-air parachute systems, drastically reducing the risk of entanglement during malfunctions and enabling safer transitions to reserve deployment.^[3] Today, the 3-ring remains ubiquitous in skydiving gear worldwide, with regular maintenance—such as inspecting for wear, corrosion, or misalignment—essential to ensure its functionality, often performed by certified riggers.^[1]

Overview and History

Invention and Development

The 3-ring release system was invented by William R. Booth, a pioneering skydiving equipment designer, in response to the need for a more reliable and user-friendly emergency release mechanism in sport parachuting. Prior to its development, skydivers relied on complex or force-intensive systems that could fail under stress or require multiple actions during a malfunction, prompting Booth to create a simple device that allowed for rapid detachment of the main parachute canopy from the harness with minimal physical effort.^[3]^[4] Booth's invention is detailed in U.S. Patent 4,337,913, filed on April 11, 1978, and granted on July 6, 1982, which describes an apparatus for releasably attaching parachute risers to a harness using a series of interconnected rings and loops secured by a flexible retaining element and released via a rip cord. The patent outlines the core three-ring configuration, where each ring interlocks with the next to provide progressive mechanical advantage, enabling quick disconnection of all risers simultaneously upon activation. This setup was specifically engineered for parachute applications, emphasizing safety and ease of use in emergency scenarios.^[5] The initial prototype emerged in the mid-1970s, featuring larger rings sourced from common hardware, and was first commercially introduced in 1976 through Booth's company, Relative Workshop (later known as United Parachute Technologies). Early versions used oversized rings suitable for heavier webbing, but challenges arose in adapting the system for sport skydiving's lighter equipment, leading to refinements that scaled the rings down for compatibility with thinner Type 17 nylon webbing commonly used in civilian risers, distinct from bulkier military-grade applications. These adjustments improved portability and reduced weight while maintaining the system's reliability.^[6]^[4]^[7]

Adoption in Skydiving

The 3-ring release system, invented by Bill Booth in 1976, experienced rapid acceptance within the skydiving community following its introduction, supplanting earlier pin-and-keeper mechanisms that required more complex operations and higher physical force for emergency cutaways.^[4]^[8] By the early 1980s, it had become the predominant release method in recreational skydiving due to its mechanical simplicity, reliability, and reduced risk of failure during high-stress malfunctions.^[9] The United States Parachute Association (USPA) played a pivotal role in formalizing its use, endorsing the system as the standard for main canopy releases and incorporating detailed maintenance and operational guidelines into the Skydiver's Information Manual (SIM) to ensure consistent safety practices among members.^[10] This integration reflected the system's quick transition from innovation to essential equipment, with USPA training programs emphasizing its disassembly, cleaning, and inspection to prevent issues like riser memory or corrosion.^[11] The adoption of the 3-ring system significantly enhanced emergency procedure efficiency, contributing to broader safety improvements in skydiving by streamlining cutaways and reducing complications under open canopies, which helped drive down overall fatalities from peaks in the 1970s.^[12] Incident data from USPA records show a marked decline in canopy-related deaths as the system became ubiquitous, underscoring its role in making malfunctions more survivable without exhaustive numerical breakdowns per era.^[13] Beyond recreational use, the 3-ring system gained traction in military applications, including U.S. Army Special Forces freefall operations, where it supports rapid riser detachment in tactical jumps.^[14] Internationally, it spread through skydiving federations aligned with the Fédération Aéronautique Internationale (FAI), establishing it as a global benchmark for reserve activation reliability by the mid-1980s.^[3]

Design and Components

Ring Configuration

The 3-ring release system consists of three interlocking rings of decreasing size, arranged in a sequential configuration to connect the skydiving harness to the main parachute risers securely under load while enabling controlled release. The largest ring, designated #1, is permanently attached to the main lift web of the harness, serving as the anchor point. The middle ring, #2, passes through #1, linking it to the subsequent components. The smallest ring, #3, passes through #2 and is positioned at the riser end, with the riser connected to #3 via a dedicated loop that threads through both the small ring and a grommet on the riser's harness-side end. This setup ensures the rings lie parallel in a stacked, snowman-like alignment, optimizing stability and load transfer.^[15]^[16] The functional layout relies on the geometric interlock of the rings, where each smaller ring nests within the previous one, combined with the loop's path to generate friction-based retention. The loop, typically a durable nylon cord, follows a simple threading: it passes through the #3 ring and the riser's grommet, forming a girth-hitch-like connection that distributes tension progressively from the riser to the harness. This configuration creates multiple friction points along the loop's path, holding the system intact under dynamic loads without requiring additional fasteners. The rings are commonly made of stainless steel for corrosion resistance, though the precise material properties are secondary to the layout.^[15]^[17] In standard models, the rings exhibit specific dimensions to accommodate typical skydiving loads: #1 measures approximately 3 to 4 inches in outer diameter, #2 about 1.75 inches, and #3 around 1.25 inches, with inner diameters scaled proportionally to allow smooth passage and minimal binding. The angles formed by the interlocked rings—typically near 180 degrees when aligned under tension—ensure even force progression across stages, preventing premature slippage. This geometry has evolved from larger original designs to compact mini-ring variants for reduced weight in modern rigs.^[18]^[19] The system is engineered to withstand deployment forces equivalent to 5-10g on the jumper's weight, distributing tension across the rings and loop to avoid localized stress concentrations. For instance, testing on configurations rated for a 300-pound exit weight at 170 knots has recorded average peak loads of 7,629.5 pounds, with the interlocking design and loop friction effectively managing these impacts across both risers.^[15]^[17]

Materials and Attachments

The 3-ring release system primarily employs rings fabricated from 316L stainless steel, selected for its superior corrosion resistance and strength in aerospace applications. This austenitic stainless steel is cold-forged to enhance durability without heat treatment, providing a polished finish that reduces friction and wear during operation.^[18]^[20] The connecting cables consist of stainless steel wire coated with nylon or Teflon for low-friction performance and protection against environmental degradation, typically in diameters of 0.062 to 0.080 inches to balance flexibility and tensile strength.^[21] In terms of attachments, the risers, made from Type 17 nylon webbing, connect to the #3 ring via a locking loop that threads through the ring and a grommet on the riser's harness-side end, with the loop ends sewn securely to the riser. The largest (#1) ring is fixed to the main lift web of the skydiver's harness, typically by stitching, while the cable housing is enclosed in a Velcro-sealed pouch, often padded with Cordura fabric, to prevent snags and contamination.^[22]^[21] The system's components are engineered to withstand static loads ranging from 2,000 to 5,000 pounds, with the small ring demonstrating a tensile strength of approximately 2,900 pounds before failure, offering a margin of safety under typical deployment forces. Stainless steel construction inherently resists ultraviolet radiation and salt-water corrosion, supporting use in diverse environments including coastal or marine settings.^[18]^[6]^[23] Manufacturing adheres to FAA Technical Standard Order (TSO) C23 requirements for personnel parachute assemblies and components, ensuring compliance with minimum performance standards for strength, reliability, and marking.^[24]^[17]

Operation and Mechanics

Cutaway Procedure

The cutaway procedure in the 3-ring release system is a user-activated emergency process designed for rapid separation of the main parachute canopy when it becomes uncontrollable or unlandable, such as in cases of line twists, bag locks, or structural damage. The skydiver, typically positioned under an oscillating canopy, reaches for the yellow cutaway handle mounted on the chest strap of the harness and performs a firm, decisive pull using one hand. This action extracts the cutaway cable from the white locking loop threaded through the rings, initiating the release mechanism.^[18] The sequence of ring separation begins with the smallest ring (#3) slipping free from the white loop first, which disconnects the corresponding main riser from the harness and immediately reduces tension on the system.^[18] This is followed in rapid succession by the middle ring (#2) and then the largest ring (#1) disengaging, fully jettisoning both main risers and the attached canopy.^[18] The entire separation occurs under a user pull force of approximately 3-8 pounds, depending on system condition and load, enabling reliable operation even under dynamic canopy forces.^[18]^[25] The cutaway handle integrates with reserve canopy deployment through a reserve static line (RSL), a lanyard that connects the #1 ring to the reserve closing pin, automatically pulling the pin after main canopy separation to initiate reserve opening. If the RSL is disconnected or fails, the skydiver must immediately pull the reserve handle following cutaway. The full process, from handle pull to complete main canopy release, typically completes in under 2 seconds. Training for the cutaway procedure is mandated by the United States Parachute Association (USPA) as part of A-license requirements, emphasizing one-handed operation during canopy oscillation through repeated drills in a training harness or under canopy. Jumpers must receive ground instruction on the procedure before using unfamiliar equipment, with annual practice recommended and pre-jump gear checks required to verify handle position and cable routing. These drills ensure proficiency, particularly for students who must cut away no lower than 2,500 feet above ground level.

Mechanical Advantage

The 3-ring release system achieves its low-effort release through a combination of leverage provided by the ring configuration and controlled friction between components, significantly reducing the force needed to initiate separation under high canopy loads. Each ring functions as a class 2 lever, providing an approximate 10:1 mechanical advantage per stage, resulting in an overall force reduction factor of approximately 200:1 for the system.^[6]^[18] For instance, under a typical deployed canopy load of around 1,000 lbf per riser (totaling approximately 2,000 lbf for both risers), the required pull force on the cutaway cable is less than 5 lbf.^[26]^[18] The effective pull force depends on the load distributed across the leverage stages and friction at each interface, which is minimized by the design to ensure reliable activation. In practice, at higher loads such as 1,000 lbf per riser, measured pull forces range from 3–8 lbf in standard configurations, scaling roughly linearly with load due to increasing frictional resistance.^[26]^[25]^[27] The release occurs in staged phases under load, with the smallest ring and loop slipping first, allowing momentum to build as the middle and large rings disengage sequentially. This staged behavior prevents abrupt failure while enabling quick release. The system has been tested to handle dynamic shock loads up to 1,500 lbf without compromising the release mechanism.^[18] Compared to older skydiving release systems, such as bar or pin mechanisms, the 3-ring design dramatically lowers the required pull force from over 500 lbf under similar loads to under 10 lbf, enabling consistent activation even during freefall instability when jumper strength may be limited.^[26]^[25]

Variations and Applications

Size and Type Variations

The 3-ring release system has undergone size variations to accommodate different harness and riser configurations, with the original design featuring larger rings suited for heavier loads and thicker webbing, while scaled-down versions emerged for lighter sport equipment. Invented by Bill Booth in 1976 as a sport parachuting innovation, the initial system used larger rings compatible with type 8 webbing, providing robust attachment for military and early piggyback systems that handled substantial weights.^[6] These original large rings, often around 4 inches in diameter for the primary (#1) ring, were designed for durability under high loads, such as in military applications like the MC-4 ram air parachute system. In the early 1980s, mini-rings were introduced to pair with narrower type 17 webbing on lighter sport rigs, reducing overall system bulk and weight while maintaining functionality. Para-Flight debuted the miniature version in late 1981 alongside the Swift container system, allowing for more streamlined harnesses that weighed less than their predecessors.^[28] However, mini-rings trade some ease of operation for this reduction, though they remain reliable for standard sport loads up to 250 pounds.^[10] Type variations include oversized rings for tandem systems, which support combined weights exceeding 400 pounds, often featuring reinforced configurations to handle the added stress of instructor-passenger pairs. Some tandem rigs employ a four-ring setup to distribute load and minimize effort during release, enhancing mechanical advantage beyond the standard three-ring design. Additionally, RSL-compatible variants ensure the reserve static line attaches securely to the small (#3) ring, a standard feature across both mini and large systems for automatic reserve deployment. An example of specialized type modification is the Aerodyne Miniforce system, which elongates the middle (#2) ring for faster slippage and reduced cutaway force by up to 35% compared to traditional mini-rings, improving performance on rigs like the Icon container.^[27] Soft-grip rings, with textured or coated surfaces, offer enhanced comfort during pre-jump inspections and adjustments, reducing hand fatigue for riggers and jumpers while preserving the core release mechanics.^[20] These variations balance weight, load capacity, and user ergonomics, with the standard mechanical advantage of approximately 200:1 per riser remaining consistent across types.^[6]

Uses Beyond Standard Skydiving

The 3-ring release system has found extensive application in military freefall parachute rigs, particularly the MC-6 Personnel Parachute System employed by special forces for high-altitude, low-opening (HALO) and high-altitude, high-opening (HAHO) operations. Integrated into the harness via fabric loops and main lift webs, it facilitates rapid main canopy jettison during malfunctions, water landings, or high-wind scenarios, with the right-side release activating slightly before the left to minimize entanglement risks.^[29] The system's components, including reinforced nylon webbing harnesses and connector links, support loads up to 360 pounds and endure the rigors of tactical jumps up to 25,000 feet mean sea level, often in conjunction with body armor and automatic activation devices like the Military CYPRES 2 for reserve deployment at altitudes as low as 1,500 feet.^[14] In BASE jumping, adaptations feature mini-ring configurations for ultralight harnesses, enabling quick post-landing canopy detachment while maintaining low weight and streamlined profiles essential for object jumps. Stainless steel mini-rings, embedded in Type 8 webbing, provide non-perforating grommets for secure yet releasable connections in rear-facing integrity-style risers.^[30] However, non-releasable variants with integrated or sewn risers predominate for static line deployments, as cutaways in freefall are unintended and risky; these fixed setups prioritize simplicity and prevent accidental separation during proximity flights.^[23] Beyond BASE, the 3-ring system supports specialized aerial sports, including wingsuit flying where Squirrel's CRUX 3R harness integrates 3-ring risers optimized for low-freefall to wingsuit-appropriate containers, using 7000-pound Dyneema webbing and custom aluminum buckles for enhanced mobility and rappel compatibility. In paramotoring and acro paragliding, emergency release variants appear in harnesses like the High Adventure MK 1 Pro, which employs a 3-ring mechanism alongside dual reserve containers and foam protection for powered flight malfunctions. Non-parachute adaptations extend to stunt harnesses, such as the KZU Tracers device, which modifies the 3-ring principle with lateral side grooves to route cabling for load-bearing in theatrical flying, cinema wire work, and aerial performances, allowing instant payload release under tension.^[31]^[32]^[33] Emerging uses in the 2020s leverage the system's mechanical advantage for non-human applications, including drone payload releases where folded-ring mechanisms deploy parachutes by releasing bungees under tension via a small pin, as implemented in UAV safety systems for controlled descents.^[34] In industrial safety, multi-ring mechanical releases akin to the 3-ring—featuring side-activated pin assemblies for harness detachment—have been patented since 2017 to enhance fall protection in construction and elevated work, providing reliable, low-force separation from lanyards or anchors.^[35]

Safety and Reliability

Common Failure Modes

The 3-ring release system, while highly reliable, can experience failures primarily due to mechanical wear, human error during assembly, and environmental exposure. These issues, though uncommon, have been documented in industry testing and incident reports, with equipment-related problems contributing to approximately 10% of skydiving fatalities as of 2023.^[36] Most failures stem from cumulative wear rather than sudden defects, emphasizing the need for vigilant inspection.^[17] Mechanical failures often involve component degradation over time. Cable stripping, where ends fray due to repeated friction and lack of lubrication, is a frequent issue; nylon-coated cables require monthly oiling to prevent binding, while Teflon-coated variants need inspection every 180 days.^[17] Ring cracks can arise from manufacturing variances or fatigue, leading to binding if tolerances exceed acceptable limits; forged steel rings must be inspected for plating damage or cracks, as they remain intact in fatigue tests only up to the point of adjacent riser failure.^[18]^[1] Human errors, such as misrigging, account for a notable portion of incidents, including twisted loops or incorrect routing that impedes release. For instance, improper reserve static line (RSL) attachment has been reported in gear checks, where the line passes through the wrong ring, potentially causing delays.^[37] RSL entanglement during turbulent deployments can also occur, as seen in cases where fabric or lines snag the assembly post-cutaway, complicating reserve deployment.^[38] Environmental factors accelerate wear on unprotected components. Corrosion from saltwater exposure reduces steel strength if untreated, necessitating rinsing within 8 hours of immersion and removal from service for cadmium-plated parts exposed longer than 6 hours; stainless steel alternatives mitigate this but are costlier.^[17] Overall, USPA data indicate low equipment failure rates, predominantly linked to wear rather than design flaws; as of 2024, equipment issues contributed to about 10% of the 9 total U.S. skydiving fatalities, with a record-low overall rate.^[39]^[40] variation-specific risks, such as tighter tolerances in mini-rings, can exacerbate binding in high-stress scenarios.^[40]

Risk Mitigation

The 3-ring release system incorporates several design features aimed at enhancing reliability and preventing failures during emergency cutaways. A key element is the Collins lanyard, a redundant safety line that connects the cutaway cable on the non-reserve static line (RSL) side to the reserve pin, ensuring both risers release even if one riser fails or the RSL malfunctions.^[40] Flexible metal housings in modern iterations, such as those in the CURV system, automatically close after release to minimize snag risks and maintain smooth cable operation under varying loads. In high-load scenarios like tandem skydiving, where forces can exceed 1,500 pounds per riser, mini-ring configurations are avoided in favor of standard or reinforced 3-ring setups to prevent deformation or incomplete releases under extreme stress.^[18]^[27] Training protocols emphasize proactive risk reduction through hands-on preparation. The United States Parachute Association (USPA) mandates pre-jump visual inspections of the 3-ring system, including verification of ring routing, cable continuity, and secure RSL attachment, performed by each skydiver at least three times before boarding the aircraft.^[41] For B-license candidates, USPA requirements include practical drills on assembling and disassembling the 3-ring system, often using ground simulators to simulate cutaway procedures and build muscle memory for emergency responses.^[42]^[43] Operational protocols further mitigate risks by adapting to specific jump types. Wingsuit skydivers must disconnect the RSL prior to cutaway to avoid entanglement hazards with the reserve canopy, as outlined in USPA Basic Safety Requirements, providing an override option that prioritizes controlled jettisoning over automatic reserve deployment.^[40] Post-jump, skydivers are encouraged to log cutaway pulls and measure release forces; pulls exceeding 300 pounds signal potential wear from friction or misalignment, prompting immediate inspection to prevent future hard releases.^[44]

Maintenance and Inspection

Routine Checks

Routine checks for the 3-ring release system are essential to ensure its reliability and prevent malfunctions during skydiving operations. According to United States Parachute Association (USPA) guidelines, pre-jump inspections should be conducted daily before each jump, involving a visual and functional verification of the system's assembly and condition.^[45] Additionally, professional inspections by an FAA-certificated rigger are required at least every 180 days during reserve parachute repacks, which effectively provide semi-annual oversight, though some manufacturers align with annual professional reviews as part of broader equipment servicing.^[17] These checks also include clearing foreign object debris (FOD), such as dirt or grime, from the loops and housing to avoid binding or interference.^[16] Visual inspections form the core of routine maintenance, focusing on detecting wear that could compromise the system's integrity. Jumpers and riggers should examine the rings for burrs, cracks, or sharp edges using magnification, such as a 10x loupe, to identify minute defects that might cause snags during release.^[17] The release cable must be inspected for frays, nicks, or kinks, with any such damage prompting immediate replacement to maintain smooth operation.^[45] Riser webbing around grommets and the white retaining loop should be checked for fraying, strains, or twists, ensuring proper routing where each ring passes through only one other ring and the retaining loop secures the top ring and cable housing end.^[16] Corrosion on metal components, if present, indicates environmental exposure and requires attention to preserve structural strength.^[17] Functional tests verify the system's operational readiness without applying full load. A dry-run pull of the cutaway handle, performed monthly by owners, should demonstrate smooth cable movement through the housing with less than 5 pounds of resistance to simulate emergency conditions effectively. Owners should also perform monthly disassembly and reassembly of the 3-ring system, as recommended by USPA, to inspect and clean internal components, ensuring each ring passes through only one other and the retaining loop is properly secured. Initial procedures should be supervised by a certified rigger.^[45] This test confirms the absence of binding and ensures the rings release sequentially without snagging, as excessive friction could increase pull force under dynamic loads.^[16] During pre-jump routines, the Reserve Static Line (RSL) connection and overall assembly should be confirmed to operate fluidly.^[45] Recommended tools enhance the precision of these checks. Calipers are used to measure ring alignment and webbing dimensions for any deviations from manufacturer specifications, while food-grade silicone spray or lubricant is applied to cables during cleaning to restore smooth gliding and reduce friction.^[17] Clean, lint-free cloths aid in removing residue without introducing contaminants.^[16] All procedures should follow the equipment owner's manual, with initial owner maintenance ideally supervised by a certified rigger to build proficiency.^[45]

Repair and Replacement

Repair of the 3-ring release system is generally limited to minor maintenance tasks that owners can perform, such as cleaning cables and massaging the webbing to remove set memory, but any structural repairs, including resewing frayed attachments, must be conducted by an FAA-certificated senior or master rigger in accordance with federal regulations.^[46]^[47] Major alterations or repairs to the harness-container system, including the 3-ring components, require the expertise of a master rigger or the manufacturer to ensure compliance with Technical Standard Order (TSO) specifications and safety standards.^[17] The practical repairs for the 3-ring system primarily involve the locking loops, which can be addressed if wear is detected during routine disassembly.^[48] Replacement of worn components in the 3-ring system is essential for maintaining reliability, with cables and loops replaced when nicks, corrosion, kinks, or excessive wear are observed during inspections.^[45] Risers should be replaced if fraying, strains around grommets, or damage beyond serviceable limits occur, as continued use could compromise the system's mechanical advantage and release function.^[45] Replacement costs for main risers typically range from $165 to $266 for a pair, depending on the manufacturer and webbing type.^[49]^[50] The United States Parachute Association (USPA) Skydiver's Information Manual (SIM), particularly Section 5-3 on equipment maintenance, mandates that all repairs and replacements be documented in a logbook, with certificated riggers required to retain records for at least two years detailing the work performed, dates, and serial numbers.^[45] For tandem systems, which involve higher loads and complexity, all maintenance and repairs to the 3-ring release must be performed by or under the direct supervision of an FAA-certificated rigger to meet operational safety requirements.^[45]^[51] Following any repair or replacement, the 3-ring system undergoes a functional verification, including a static load assessment to at least 1,000 pounds per riser as part of manufacturer-recommended testing protocols to confirm integrity before reuse.^[18] This step ensures the system's progressive reduction in tension operates correctly under simulated deployment forces.^[18]

References

[1]
Gear wisdom: 3-rings - Skydivemag
Apr 14, 2023 · The 3 ring-system is a skydiving safety device invented by Bill Booth in the mid 1970s. When we have a malfunction and need to cut away, the cutaway handle is ...
[2]
Piggybacks and Three-Ring Circuses—A Slightly Irreverent Look Back at Skydiving Equipment
### Summary of Three-Ring Release System
[3]
Bill Booth | International Skydiving Museum & Hall of Fame
Introduced in the late 1970s, the three-ring system revolutionized emergency procedures by allowing jumpers to cut away their main canopy with unprecedented ...
[4]
Piggybacks and Three-Ring Circuses—A Slightly Irreverent Look ...
But Booth's elegant 3-ring release, inspired by a system used for tethered balloons, required the jumper merely to pull a cutaway handle first, then the ...
[5]
US4337913A - Means for releasably attaching strands
This invention provides an apparatus for releasably attaching all strands or risers of a parachute from a harness of the parachutist and comprises a series ...Missing: history | Show results with:history
[6]
[PDF] The Booth 3-Ring Release System - ParaORG
The Booth 3-Ring Release System is the first successful canopy release device to be solely developed for sport parachu- ting. First introduced in 1976, the ...
[7]
Welcome to UPT - United Parachute Technologies
The second invention, and perhaps Bill's greatest contribution to the sport, was the invention the 3-Ring Release System. In 1983, Bill received the ...Missing: motivation | Show results with:motivation
[8]
Most Important Moments in Skydiving History
The three-ring release system was invented by Bill Booth and patented in 1978 as a means of attaching (and detaching) a canopy from its harness. 3 Ring Release ...Missing: motivation challenges
[9]
Always Innovative - Skydivemag
Jun 22, 2021 · Just one year later in 1976, the second invention was created, arguably Bill's greatest contribution to skydiving – the 3-Ring Release System.Missing: prototype | Show results with:prototype
[10]
Glossary - United States Parachute Association
MINI THREE RING Refers to a scaled-down version of the original three-ring release system. (see also THREE-RING RELEASE). MINOR ALTERATION An alteration ...
[11]
[PDF] SIM.2003.pdf
Owner maintenance of three-ring release system. (required for A license) a. Disassemble the system every month to clean the cable and massage the ends of the ...
[12]
Skydiving Then and Now—50 Years of Change
Jul 1, 2019 · Executing emergency procedures today using a 3-ring release system is much simpler and more streamlined. The decision-making and execution ...
[13]
A Record Low—The 2018 Fatality Summary
Apr 1, 2019 · In 2018, 13 people died during skydives in the U.S. This is the lowest annual fatality number since 1961, when USPA (then the Parachute Club ...Missing: 1970s | Show results with:1970s
[14]
[PDF] Special Forces Military Free-Fall Operations October 2014
Aug 18, 2016 · Vector-3 System and the Tandem Offset Resupply Delivery ... snap hooks to the large equipment attachment rings directly below the three-ring ...Missing: adoption FAI
[15]
[PDF] OWNER'S MANUAL - Sun Path
3 Ring Release System Inspection ....................... 1-3. Donning the Harness ........................................... 1-4. Correct Friction Adapter ...
[16]
The Loft: 3-RING CUTAWAY SYSTEM MAINTENANCE | Sun Path
Dec 11, 2017 · Now reassemble your 3-ring system to the correct snowman-like configuration. Medium Ring through Large Ring and Small Ring through Medium ...
[17]
[PDF] Parachute Rigger Handbook (Change 1)
systems equipped with a 3-ring release system. • Description: Replacement of damaged or missing. 3-ring release housings. • Authorized repairmen ...Missing: FAI | Show results with:FAI
[18]
[PDF] Testing and Analysis of Components for 3-Ring Systems - Tylaska
standard Mini 3-Ring release systems. ○ We are presenting a view of our analysis and development to provide information on the safety of these new components.
[19]
NO. 3 STYLE RING - Para Gear
Outside diameter 1 15/64". Inside diameter 7/8". Shipping Weight: 2 oz. (60g). Mini 3-Ring Systems consist of: Large Ring H3800B H3800S. Medium Ring H3860BMissing: standard | Show results with:standard
[20]
Cold-Forged Stainless Steel 3-Ring Hardware - Tylaska
4-day delivery 60-day returnsTylaska Cold-Forged 316L stainless steel 3-Ring hardware. 2x stronger than MIL-S-5626, with superior corrosion resistance for parachute safety. Shop now!Missing: materials 17-4 PH
[21]
3-ring release system - Wikipedia
The 3-ring release system is a parachute component that is widely used by sport skydivers and military freefall parachutists to attach the two risers of a main ...
[22]
JAVELIN 3 RING RELEASE - Para Gear
CPX/TALON/TELESIS 3 RING RELEASE ; STAINLESS STEEL CURVED PIN ; RATCHET SET FOR OXYGN ; SKY TIE MAGNETIC SLIDER KEEPER ; CYPRES AAD LOOP MATERIAL - 50 METER SPOOL ...
[23]
MINI THREE RING RELEASE RISERS - Para Gear
Factory replacement risers. These risers are made of 1" wide Type 17 webbing. Length 20". Available in black only. Shipping Weight: 2 lbs. (910g) ...Missing: nylon | Show results with:nylon
[24]
3-Ring Risers - Squirrel Wingsuits
Secondly, it is critical that skydive 3-rings are easily releasable under load in order to facilitate safe cutaways. BASE jumping 3-ring risers are not designed ...
[25]
[PDF] AC 105-2E Ed Upd 2 - Federal Aviation Administration
Dec 4, 2013 · The TSO-C23 series contains the minimum performance standards for parachute assemblies and components. Manufacturers design and test new ...
[26]
Mechanical advantage of the 3-ring release system
Feb 4, 2018 · The current configuration, again as described by Bill Booth, is that there is a ten to one reduction of force for each ring. If one ignores the ...
[27]
[PDF] Reversed vs. Non-Reversed Risers - ParaORG
Aug 11, 1998 · Therefore, NO mechanical advantage is added ... Relative Workshop has a published specification for the 3-ring release system, and most.
[28]
[PDF] “Re-designing the three-ring release system” Author: Ian Bellis
This patented new system actually addresses the engineering behind the three-ring release system and effectively reduces forces on the cutaway cable by an ...Missing: Type 17 webbing
[29]
[PDF] PSB#110186 3-ring Release Periodic Maintenance & Mini 3-ring ...
Nov 1, 1986 · BACKGROUND. The Booth 3-Ring Release System has been in use for three years, with excellent results. Although the system is at least as durable ...
[30]
Three-ring mistake | Flight Safety Australia
Mar 16, 2016 · It is something that can only happen on a tandem rig due to the larger 3 ring assembly. Between landing and packing for the next jump the middle ...
[31]
TM-10-1670-327-23-P MC-6 Personnel Parachute System NSN ...
Chapter 1 GENERAL INFORMATION, EQUIPMENT DESCRIPTION, AND THEORY OF OPERATION FOR MC-6 PERSONNEL PARCHUTE SYSTEM
[32]
3 Rings Risers - AdrenalinBASE
The 3 RINGS RISERS are mini ring type and have non perforating grommet, all rings are stainless steel built in Type 8 webbing.Missing: system ultralight
[33]
BASE Jumping harness container CRUX 3-Ring - Squirrel Wingsuits
The CRUX 3R is a versatile 3-ring system with modern geometry, custom buckles, 7000lb Dyneema webbing, integrated rappel loops, and a mid-long container.
[34]
MK 1 pro | High Adventure
The MK 1 pro is designed for acro, has a 3-ring release, 13cm foam protection, two emergency containers, and a 9 liter back pocket.
[35]
KZU - Tracers stunt harnesses and safety equipment
In stock 7–18 day deliveryDevice for instant release the load. Based on parachute 3 ring release mechanism but has two grooves on the sides, which becomes a convenient for placing cable.Missing: skydiving | Show results with:skydiving
[36]
3 Ring Release - Aerofoam UAV Systems
The 3 Ring Release is a mechanism used to deploy parachutes, releasing bungees under tension using folded rings and a small pin.
[37]
US9771159B1 - Multi-ring mechanical release with side activation
Sport jumpers use a release that is referred to as a 3-Ring Canopy Release. The 3-Ring Canopy Release is a series of three interlocking rings held closed by a ...
[38]
A Step Backward—The 2022 Fatality Summary
Apr 3, 2023 · After four years of significantly reduced annual civilian skydiving fatalities in the United States, including a record low of only 10 ...
[39]
Keep an Eye Out | Improper RSL Routing
May 1, 2020 · The rigger noticed that the reserve static line was routed incorrectly, with the RSL passing through the large ring of the 3-ring system and connecting to the ...
[40]
Friday Freakout: Skydiver Slashes Main Parachute With Hook Knife ...
Mar 6, 2020 · ... 3-ring assembly -- which had to be cut way with a hook knife to avoid an entanglement with her reserve ... incidents cannot be prevented but ...
[41]
https://uspa.org/sim/4-4
[42]
Chapter 4 - United States Parachute Association
If the upper jumper is lower than the bottom skin of the other canopy, that jumper should clear lines and fabric away from their body, harness and three-ring ...
[43]
Did I explain the 3 ring release and RSL correctly? - SkyDiving
Apr 17, 2019 · Three ring release: The cutaway handle has two yellow cords of different lengths. The shorter yellow cord runs up the right side of the shoulder ...
[44]
[PDF] SIGMA TANDEM MANUAL MAN-013 Rev 2.1 Page i
Sep 11, 2024 · The Sigma Tandem is a harness and container system, considered the safest and most reliable on the market, with a main canopy, drogue, and ...Missing: Basik | Show results with:Basik
[45]
United States Parachute Association > Experienced Skydivers > SIM ...
C. Equipment Checklist · helmet: proper fit and the chin strap threaded correctly · goggles or glasses: secure and clean · three-ring release system: properly ...
[46]
B License Study Guide | Skydive Fundamentals
All persons engaging in skydiving must: possess at least a current FAA Third-Class Medical Certificate or carry a certificate of physical fitness for skydiving ...
[47]
https://www.faa.gov/documentlibrary/media/advisory_circular/ac%2520105-2d.pdf
[48]
3-Ring Maintenance - Skydive Spaceland Dallas
Dec 28, 2011 · Service monthly by lubricating cutaway cables, cleaning with paper towel, massaging rings, and checking continuity. This prevents hard cutaways.
[49]
CANOPY TRACKING DEVICE FOR SKYDIVING EQUIPMENT
May 26, 2016 · As we readily understood by those of skill in the art, the 3-ring system includes a first ring 30 which is looped through a second ring 32. The ...
[50]
Rigging Innovations | The World's Most Advanced Skydiving Rigs
RI is the world leader in the design and manufacture of skydiving harness container systems. We produce innovative skydiving rigs for the sport, military, ...Curv · Skydiving containers · Documents · Telesis 3.0
[51]
[PDF] USPA SKYDIVER'S INFORMA TION MANUAL
The manual provides basic skydiving standards and recommendations for safe skydiving, and describes USPA programs. Compliance with Basic Safety Requirements is ...
[52]
Ask a Rigger—What kinds of maintenance and repair can owners do ...
Aug 24, 2021 · Your rig still needs maintaining, but it's primarily rigger maintenance. Even the 3-ring system service interval has been extended from monthly ...Missing: guidelines manufacturer
[53]
[PDF] AC 105-2D - Advisory Circular - Federal Aviation Administration
May 18, 2011 · (3) Major repairs may be made only by an appropriately rated master rigger or a manufacturer of approved parachute components. The ...
[54]
[PDF] PARACHUTE RIGGER HANDBOOK 2005 - ParaORG
The only items that are practical for repair are the 3-ring locking loops and the toggle mounting/Velcro® assembly. Once the webbing begins to ...
[55]
Risers - Para Gear
$$165.00Factory replacement risers. These risers are made of 1" wide Type 17 webbing. Length 20". Available in black only. Shipping Weight: 2 lbs. (910g). Price: ...
[56]
Risers | Store - Sun Path Products
View our selection of risers including Type 17 with Easy Grip or Standard Dive Loops.
[57]
[PDF] AC 105-2E - Advisory Circular
Dec 4, 2013 · While the regulations do not require an FAA medical certification, the FAA urges prospective skydivers to receive a physical examination prior ...