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Obturating ring
Obturating ring
Obturating ring
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An obturating ring is a ring of relatively soft material designed to obturate under pressure to form a seal. Obturating rings are often found in artillery and other ballistics applications, and similar devices are also used in other applications such as plumbing, like the olive in a compression fitting. The term "O-ring" is sometimes used to describe this kind of pressure seal.

Ballistics uses

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Welin screw breech block[1] showing the protruding head of the mushroom-shaped de Bange obturator, with its obturating ring between the head and the screw

Obturating rings are common in artillery, where the steel or cast-iron casing of the shell is too hard to practically deform to provide a tight seal for the propellant gases. An obturating ring which is called driving band made of a softer material is the standard solution for that problem. Mortar bombs also use obturating rings to provide a seal around the projectile. [citation needed] Recoilless rifles and some artillery use rings with a reverse impression of the rifling cut in them for a tighter seal even at very low pressures.[clarification needed]

Another obturating ring may be used on sliding/falling breech-blocks from the opposite side of the chamber to provide a tight seal there if the charge is bagged and lacks a case (examples include early Krupp guns to Royal Ordnance L11 to M777). The obturating ring provides the sealing that would normally be provided by a cartridge case.

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Obturating ring

View on Grokipedia
from Grokipedia
An obturating ring is a mechanical seal, typically a band or segmented ring of compressible or expandable fitted into a groove on the body of a , designed to expand radially under the of gases during firing to create a gas-tight barrier against the interior of the or mortar barrel. This prevents the escape of gases around the , thereby maximizing the efficiency of propulsion, ensuring consistent muzzle velocities regardless of barrel temperature, and enhancing the range and accuracy of the munition. In mortar ammunition, such as 60mm, 81mm, or 120mm rounds, the obturating ring is positioned at the widest section of the projectile body, often near the base, and is commonly made from soft metals like aluminum or alloys, sometimes coated with low-friction materials such as (PTFE) to reduce wear on the barrel. Upon ignition of the charges, the ring deforms to engage the bore, wiping away residue and trapping gases until the projectile exits the muzzle, after which it may fragment or separate. For rifled systems, advanced variants known as slipband obturators incorporate materials like for the inner sealing layer and /6 for the outer band, often lubricated with , to not only seal gases but also allow controlled slippage that reduces rotational spin on fin-stabilized projectiles, enabling their use in guns designed for spin-stabilized rounds. These designs balance sealing integrity with management, preventing excessive rifling-induced rotation while maintaining during high-pressure firing. Historically, the development of obturating rings marked a significant advancement in design, particularly with the introduction of variants in the mid-20th century, which improved reliability over earlier metal or compositions by providing better expansion and reduced barrel . Modern iterations continue to evolve for compatibility with precision-guided munitions, such as mortar guidance kits, where the ring integrates with warhead bodies filled with high explosives like .

Fundamentals

Definition

An obturating ring is a ring-shaped component, typically constructed from a soft, deformable , positioned on a to expand radially under the influence of high gas , thereby creating a gas-tight seal against the interior surface of a or barrel and preventing the escape of gases. This seal ensures efficient transfer of to propel the while minimizing energy loss and barrel erosion from gas blow-by. Obturation refers to the broader process of achieving such a seal through expansion or deformation, with the obturating ring serving as a dedicated implement to facilitate this in dynamic, high- environments. The term derives from the Latin obturare, meaning "to stop up" or "to block," reflecting its function in obstructing gas flow. While primarily utilized in to maintain bore integrity, the principle of an obturating ring extends to broader sealing applications in systems requiring of fluids or gases under , such as certain mechanical and hydraulic interfaces.

Principle of Operation

Upon ignition of the charge in an weapon, the resulting rapidly generates high-pressure gases, typically reaching chamber pressures of 200 to 400 MPa depending on the and type. These gases exert on the obturating ring, which is positioned to seal the interface between the breech or and the barrel bore. Initially, a slight reduction in pressure may draw the ring slightly outward from its groove, but the subsequent surge of gas enters the space behind the ring, causing it to deform radially and expand uniformly to fill any clearances. This expansion occurs through a combination of elastic and plastic deformation, where the ring's soft material compresses and flows under the intense , conforming tightly to the barrel's inner surface. The sealing action is instantaneous, creating an effective barrier that prevents "blow-by" of gases around the or breech, thereby maintaining maximum pressure behind the to optimize propulsion and . In systems using separate-loading , where bagged lacks a rigid metal casing, the obturating ring—often composed of split or segmented elements—expands via a mechanism that compresses an inner pad, forcing the segments outward into metal-to-metal contact with the bore. This dynamic ensures gas containment during the brief but extreme conditions of firing, with the ring briefly exposed to gas temperatures exceeding 2,000°C while deforming without fracturing prematurely. Unlike rigid seals, which cannot accommodate the barrel's , , or minor manufacturing irregularities, the obturating ring's soft, deformable nature provides adaptive sealing essential for without self-contained metal cases. This flexibility allows the ring to wipe residue from the bore while forming a gas-tight fit, minimizing loss and enhancing overall efficiency without relying on the structural integrity of a cartridge case. Post-expansion, the ring may partially extrude or break apart as pressures drop, facilitating extraction, but its primary role is fulfilled in the initial high-pressure phase.

Historical Development

Origins in the 19th Century

The development of obturating rings on projectiles paralleled the advent of in the mid-19th century, as guns transitioned to designs requiring precise gas sealing to engage and maximize velocity. Early systems, such as the introduced in 1858, employed elongated projectiles with lead sheathing or coatings that deformed under pressure to seal the bore and follow the rifling grooves, preventing gas escape and ensuring rotation. These soft metal layers served dual roles as both driving surfaces and obturators, though they often led to excessive barrel and inconsistent performance due to the sheathing's tendency to strip or smear. In parallel, the American Hotchkiss and Parrott rifles of the utilized wrought-iron projectiles fitted with or lead bands inserted into grooves near the base, marking an early form of dedicated obturating rings. These bands expanded radially upon firing to create a gas-tight fit against the barrel, addressing the limitations of full sheathing while enabling higher muzzle velocities in rifled bores. However, material brittleness and manufacturing inconsistencies limited their reliability, particularly in high-pressure applications, highlighting the need for more durable, expandable designs. By the late , the adoption of separate cartridge cases in fixed reduced some sealing demands on projectiles, but rifled continued to rely on obturating rings for forward gas containment. Innovations like the French 75mm quick-firing gun of 1897 incorporated (copper-zinc alloy) bands, which provided better expansion and reduced wear compared to pure lead, establishing a standard for large-caliber shells.

Key Innovations and Adoption

The early 20th century saw refinements in obturating ring design, with artillery systems like the French 75mm and British 18-pounder field guns using sintered copper driving bands that balanced sealing integrity with minimal barrel erosion. These bands, typically 90-95% copper, deformed under pressures of 15,000-20,000 psi to engage while wiping residue, enabling sustained firing rates and consistent in prolonged engagements. In naval applications, such as the 12-inch guns of the era, multi-groove obturating rings prevented losses, contributing to ranges exceeding 20,000 yards. During , obturating rings remained predominantly metallic, with the U.S. 155mm M1 projectiles featuring replaceable bands coated for corrosion resistance, ensuring gas retention at chamber pressures up to 30,000 psi. However, wartime demands for higher velocities and reduced maintenance spurred experimentation with composite materials, foreshadowing postwar shifts. The era also saw the integration of obturating functions with fin-stabilized designs in some anti-aircraft rounds, where bands allowed minimal spin for stability. Post-World War II innovations emphasized non-metallic obturating rings to mitigate barrel wear and enhance compatibility with bag or modular charges in self-propelled systems like the . By the 1950s, plastic variants—often or nylon-based—replaced in many applications, offering superior elasticity under pressures up to 40,000 psi and lasting 50-100 rounds before replacement. These materials, sometimes lubricated with , reduced erosion by 50% compared to metal bands and facilitated precision-guided munitions, such as those with warheads. Further advancements in the era included segmented rings for recoilless weapons and mortars, improving reliability across diverse calibers.

Technical Design

Components and Structure

Obturating rings are typically composed of a primary sealing element designed to expand radially under , forming a gas-tight barrier within the system. This core component often takes the form of a cup-shaped or toroidal ring, which may incorporate additional supportive elements such as an inner expander to facilitate uniform deformation. In sectional designs, the ring consists of multiple segments, usually at least two semi-annular pieces, that interlock to create a continuous encircling . Each segment features complementarily shaped ends—one with a curved recess and the other with a convex cam—that join securely, ensuring the assembly maintains integrity before and during expansion. These sectional configurations allow for precise fitting and controlled expansion, contrasting with monolithic designs that form a single, undivided ring for simpler integration. For breech-mounted obturators, multi-ring assemblies are common, comprising an inner backup ring, an outer camming ring, and a central obturating ring nested within a cylindrical recess on the breechblock's front face. The inner and outer rings feature beveled peripheries that interact to drive the central ring forward and outward upon pressure application, with an annular retainer securing the stack against axial movement. Integration occurs by seating the ring assembly into dedicated grooves or recesses, such as those machined into the breechblock or along the projectile's body. In projectile-based systems, the obturating ring is positioned in a groove at the base or mid-body, typically below the rotating band that engages the rifling for spin stabilization, allowing the obturating element to seal against the bore without interfering with rifling grooves. For breech systems, the rings slot into the block's face recess, aligning perpendicular to the barrel axis to seal the closure upon expansion. Structural variations distinguish static breech rings, which are solid or multi-layered for fixed mounting and high-pressure , from expandable projectile bands that prioritize slippage and radial conformity to the tube's inner surface during forward . This expansion, driven by gas as per operational principles, ensures the ring deforms to fill any gaps without permanent distortion.

Materials and Manufacturing

Obturating rings require materials that are softer than the barrel to enable deformation for effective gas sealing while maintaining resilience under and temperature. Traditional materials for driving bands, which function as obturating rings, include and (a 90% -10% ), valued for their malleability and ability to engrain into grooves. These metals provide a reliable seal but are relatively heavy and costly. Modern obturating rings increasingly utilize polymers to achieve low-friction sealing and reduced weight. Common choices include (PVC) for mortar applications, though it has been largely replaced by to avoid contamination that causes barrel and pitting. (PTFE) is applied as a or full ring for its exceptional low-friction and chemical resistance, while and offer disposability and compatibility with high-temperature environments through composites. Silicon rubber is also used in some breech designs for its Shore A of 50-70, providing flexible sealing. and excel in malleability for durable seals but contribute to higher material costs and barrel wear over time, whereas polymers like and PTFE provide advantages in lightweight design and ease of replacement, albeit with potential limitations in extreme heat durability. Manufacturing processes are tailored to the type to ensure precision and uniformity, critical for preventing gas leaks from inconsistencies. Metal rings, such as those made from or aluminum alloys, are commonly produced via or stamping of strip blanks into semi-annular segments, which are then interlocked to form complete rings; optional PTFE or coatings are applied to reduce friction. rings, including or variants, are fabricated through injection molding or in precision molds, often incorporating fibers for enhanced thermal stability and minimal shrinkage. For polyurethane-based breech pads, with curing agents like MOCA ensures flexibility across a broad temperature range from -65°F to 125°F. Rigorous quality controls, such as dimensional verification and testing for hardness and uniformity, are implemented throughout to guarantee reliable sealing performance.

Applications

In Conventional Artillery

In conventional artillery systems, such as rifled howitzers and guns using separate-loading with charges, the obturating ring—often integrated as part of the on the —seals the space between the and the barrel bore to prevent the escape of propellant gases. This forward obturation maximizes pressure on the base of the , enhancing and efficiency. The , typically made of soft metal like or modern plastic materials, expands under gas pressure to engage the , imparting spin for stability while wiping the bore clean of residue. Advanced designs, such as slipband obturators, use segmented bands with materials like and to allow controlled slippage, reducing excessive rotation on fin-stabilized projectiles while maintaining gas sealing. These are particularly useful in large-caliber systems like 155 mm howitzers, where the band is positioned in a groove on the projectile body and deforms to fit the bore . Performance ensures consistent velocities under varying conditions, with bands designed to withstand chamber pressures up to 60,000 psi. Maintenance involves inspecting ammunition for band integrity, as worn or damaged bands can lead to gas leakage and reduced accuracy.

In Mortars and Recoilless Weapons

In mortars, function as disposable driving bands integrated directly into the rounds, providing gas sealing in drop-fired systems. These rings, often constructed from lightweight or materials, are positioned around the projectile's body near its base. When the round is dropped into the barrel and strikes the fixed , the charge ignites, generating high-pressure gases that cause the ring to expand radially and conform tightly to the barrel's inner surface. This expansion seals the bore to prevent gas leakage, which would otherwise reduce and efficiency. In systems like the 60 mm mortar, the ring's design ensures consistent performance across varying barrel temperatures by maintaining gas containment until full cartridge burnout. The obturating ring also plays a key role in preventing setback during the drop-fire , where the round must remain stable against initial inertial forces upon ignition. By rapidly deforming to form a lock with the barrel upon gas buildup, the ring resists any rearward slippage of the , ensuring reliable forward acceleration and minimizing the risk of misfires or inconsistent trajectories in high-angle fire scenarios. This -integrated seal is particularly advantageous in mortar tubes, where traditional breech mechanisms are absent, and projectile stability is achieved via fins. In recoilless rifles, obturating rings or bands are engineered to seal vented barrels under dynamic conditions, balancing forward projectile propulsion with rearward gas venting for compensation. These components, typically made from soft, deformable materials such as plastic or rubber, expand or deform upon firing to conform to the , often incorporating pre-cut reverse impressions to achieve a tight seal even at low initial pressures before full venting occurs. For instance, in the Carl Gustav 84 mm system and the early 20th-century , the bands accommodate back-blast expulsion through the rear while preventing excessive gas bypass around the projectile, thereby maintaining pressure differentials essential for effective launch. The soft material takes impressions during deformation, enhancing spin stability without excessive barrel wear. The lightweight, single-use nature of these obturating rings in mortars and recoilless weapons significantly reduces logistical burdens compared to reusable breech seals, as they eliminate the need for separate components and simplify field maintenance. Modern examples include improved sabot rounds featuring sectioned obturating rings, which divide into segments for more uniform radial expansion and discard, optimizing performance in extended-range applications while minimizing residue buildup in the barrel. This design prioritizes reliability in open-breech environments, where rapid reloading and minimal weight are critical.

References

  1. https://patents.google.com/patent/US3687079A/en
  2. https://apps.dtic.mil/sti/tr/pdf/ADA243037.pdf
  3. https://osmp.ngo/mechanical_feature/obturating-rings-gas-check-bands/
  4. https://apps.dtic.mil/sti/tr/pdf/ADA474244.pdf
  5. https://ndia.dtic.mil/wp-content/uploads/2010/armament/TuesdayCumberlandKellyHanink.pdf
  6. https://pmc.ncbi.nlm.nih.gov/articles/PMC11991912/
  7. https://www.merriam-webster.com/dictionary/obturation
  8. https://www.researchgate.net/figure/Typical-barrel-internal-ballistic-Pressure-distance-graph-5_fig2_316465994
  9. https://sturgeonshouse.ipbhost.com/topic/1086-tanks-guns-and-ammunition/page/28/
  10. https://www.marines.mil/portals/1/publications/mcwp3_16_4.pdf
  11. https://www.military-references.com/wp-content/uploads/books/artillery/general/Army_Principles_of_Artillery_Weapons_TM-9-3305_1981.pdf
  12. https://www.sciencedirect.com/topics/earth-and-planetary-sciences/gun-propellant
  13. https://www.britannica.com/technology/artillery/Breech-loading
  14. https://www.britannica.com/technology/artillery/Ammunition
  15. http://www.navweaps.com/Weapons/WNBR_12-50_mk7.php
  16. https://apps.dtic.mil/sti/tr/pdf/ADA079666.pdf
  17. https://www.sciencedirect.com/science/article/pii/S2214914724001107
  18. https://patents.google.com/patent/US3434381A/en
  19. https://apps.dtic.mil/sti/tr/pdf/ADA156666.pdf
  20. https://apps.dtic.mil/sti/tr/pdf/ADA307520.pdf
  21. https://techlinkcenter.org/technologies/improved-obturating-ring-for-large-caliber-discarding-sabot-munitions/de6807cb-b95c-4934-8a99-fbde319e8418
  22. https://publications.drdo.gov.in/ojs/index.php/dsj/article/download/4019/2307/11662
  23. https://destructivedevices.com/product/60mm-obturating-rings/
  24. https://apps.dtic.mil/sti/tr/pdf/ADA023513.pdf
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