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Ball propellant

Ball propellant, also known as Ball Powder®, is a type of smokeless gunpowder characterized by its spherical granules, typically made from nitrocellulose and often incorporating nitroglycerin in double-base formulations, used primarily as a propellant in small arms, medium-caliber, and some large-caliber ammunition.^[1]^[2] Invented in 1933 by Fred Olsen for the Western Cartridge Company (a predecessor to Winchester), ball propellant was developed through a patented process involving the dissolution of guncotton (nitrocellulose) in ethyl acetate to form round grains, enabling faster, safer, and more cost-effective production compared to traditional extruded propellants.^[3]^[4] Commercial production began that same year, with significant adoption during World War II for U.S. and allied military applications, and it has since become the dominant propellant for over 99% of U.S. military small arms ammunition up to 20mm caliber.^[1]^[3] The manufacturing process starts with pure nitrocellulose, which is shaped into spheroids in a liquid medium through agitation, followed by solvent evaporation, surface impregnation with nitroglycerin for double-base variants, size sorting, optional coating, and drying; some types are further flattened via roller pressing to enhance burn characteristics.^[2] Produced today at the St. Marks Powder facility in Florida—owned by General Dynamics Ordnance and Tactical Systems since 1969—ball propellants offer advantages such as high loading density, low flame temperatures to reduce barrel wear, temperature stability, and over 200 specialized formulations for diverse uses including 5.56mm, 7.62mm, .50 caliber, 20mm-30mm autocannon rounds, and 60mm-120mm mortar increments.^[1]^[3] In civilian applications, variants like Winchester 231 are popular for handgun loads in calibers such as 9mm, .38 Special, and .45 ACP due to their consistent metering and performance.^[5]

History

Development and Invention

Ball propellant, a type of spherical smokeless powder, originated from efforts to repurpose surplus munitions materials in the aftermath of World War I. In the 1920s, chemist Fred Olsen, working at the U.S. Army's Picatinny Arsenal in New Jersey, experimented with salvaging tons of deteriorating single-base cannon powder composed primarily of nitrocellulose, which had been produced in excess during the war and was prone to instability due to degradation.^[3] These early investigations focused on purifying and reshaping the nitrocellulose to restore its utility, addressing the challenges of disposal and waste from outdated stockpiles.^[3] Olsen's breakthrough came after he joined the Western Cartridge Company in 1929, where he refined his process at the East Alton, Illinois facility. By 1933, he had developed a novel manufacturing method involving the dissolution of nitrocellulose in a volatile solvent like ethyl acetate, followed by agitation in a water bath to form uniform spherical granules through tumbling and solidification.^[3] This underwater shaping technique, conducted under pressure with agitating blades, produced dense, spherical particles that were safer to handle and more consistent than traditional extruded powders, which required lengthy drying times and consumed large volumes of solvents.^[6] The process's key advantage was its speed and efficiency, enabling rapid production while minimizing explosion risks during gelatinization and forming.^[6] In the 1930s, Olsen and collaborators tested experimental formulations to optimize the spheres' burn rates and stability, incorporating additives such as nitroglycerin for double-base variants and graphite coatings for lubrication and deterrence.^[3] These efforts culminated in seminal patents, including U.S. Patent 2,027,114 (issued January 7, 1936), which detailed the dispersion of gelatinized nitrocellulose globules in a non-solvent medium like water with a protective colloid to yield spherical grains, and U.S. Patent 2,175,212 (issued October 10, 1939), which further advanced solvent extraction and stabilization techniques.^[7] Co-inventors Gordon C. Tibbitts and Edward B. W. Kerone contributed to these innovations, establishing ball propellant as a foundational advancement in smokeless powder technology.^[6]

Adoption and Production Milestones

Ball propellant saw its initial widespread military adoption during World War II, where it enabled rapid scaling of small-arms ammunition production due to its efficient manufacturing process. Specifically, it was employed in .303 British cartridges using WC846 propellant and in M1 Carbine rounds with WC820, supporting Allied forces' high-volume needs.^[3] Following the war, ball propellant transitioned to civilian markets in the early 1960s, with Winchester beginning to supply its ball powder line to handloaders through distributors like the Hodgdon Powder Company, marking the start of commercial availability for reloading enthusiasts.^[8]^[3] Production underwent a significant shift in 1969 when operations moved from the original East Alton, Illinois, facility to the newly constructed St. Marks Powder plant in Crawfordville, Florida, under the Olin Corporation, which held the trademark for Ball Powder. This relocation addressed space constraints and environmental factors, with full operations commencing in 1970 and enhancing long-term scalability. In 1997, Olin sold the St. Marks facility to General Dynamics Ordnance Systems, which continues production today.^[5]^[3]^[3] In the 2010s, advancements continued with the introduction of the Winchester StaBALL series, beginning with StaBALL 6.5 in 2019, designed for improved temperature stability across extreme conditions while maintaining the spherical grain characteristics of traditional ball propellants. This innovation addressed variability in performance for precision rifle applications, such as 6.5 Creedmoor loads.^[9] As of 2025, General Dynamics Ordnance and Tactical Systems maintains leadership in ball propellant production at the St. Marks facility, supplying over 200 variants that power more than 99% of U.S. military small-arms ammunition up to 20mm, alongside commercial demands through partners like Hodgdon.^[1]

Composition

Primary Chemical Components

Ball propellant, a type of spherical smokeless powder, primarily consists of nitrocellulose as its energetic base material. Nitrocellulose, derived from the nitration of cellulose, typically features a nitrogen content of 12.6% to 13.3%, which determines its energetic properties and suitability for controlled deflagration in propellant applications.^[10] This high-nitrogen variant, often around 13.2%, enables the material to undergo rapid decomposition into gaseous products, serving as the foundational component for generating propulsive energy.^[11] In double-base formulations common to ball propellants, nitroglycerin is incorporated alongside nitrocellulose to enhance overall energy output. Nitroglycerin content typically ranges from 5% to 40%, with conventional ball propellants using 8% to 10% for balanced performance; for example, the WC844 variant contains approximately 8.2% nitroglycerin combined with 86% nitrocellulose.^[12]^[11] This liquid nitrate ester plasticizes the nitrocellulose matrix, increasing the propellant's calorific value and burn rate while maintaining structural integrity in spherical granules.^[13] Together, nitrocellulose and nitroglycerin facilitate controlled combustion by decomposing into nitrogen, carbon dioxide, water vapor, and other gases without producing significant solid residues, thus achieving the "smokeless" characteristic essential for modern firearms.^[14] This deflagration process ensures efficient energy release for projectile propulsion while minimizing fouling in gun barrels. Stabilizers are added to prevent autocatalytic degradation of these nitrate esters, as detailed in the Additives and Stabilizers section.^[15]

Additives and Stabilizers

In ball propellants, stabilizers such as diphenylamine are incorporated at concentrations of 1-2% to inhibit the decomposition of the nitrocellulose base and prevent the buildup of acidity from nitrogen oxide byproducts during storage.^[16] These stabilizers react with decomposition products to extend shelf life and maintain chemical integrity, with diphenylamine being particularly effective in single-base formulations.^[17] Deterrents, including ethyl centralite and dinitrotoluene, are added to regulate the burn rate by moderating the initial combustion velocity and promoting more uniform progression.^[16] Ethyl centralite, often at around 0.9-6%, serves dual roles as both a stabilizer and deterrent, while dinitrotoluene, used at levels up to 6% in specific ball propellant compositions like WC844, acts primarily to slow early-stage burning for safer handling and processing.^[18] Plasticizers such as dibutyl phthalate (typically 1-5%) enhance the flexibility and processability of the propellant grains, reducing brittleness and improving extrusion during manufacturing.^[16] Additionally, coatings like graphite (0-1.5%) are applied to the spherical grains to provide electrical conductivity, mitigate static electricity risks during transport and loading, and act as a lubricant to prevent aggregation—features particularly suited to the uniform, ball-shaped geometry.^[17]

Manufacturing Process

Key Production Steps

The production of ball propellant, a spherical form of smokeless powder, follows an aqueous-based industrial process that begins with the preparation of a nitrocellulose lacquer. Nitrocellulose—either freshly manufactured or recovered—along with a stabilizer such as diphenylamine, is dissolved in hot ethyl acetate solvent to create a viscous, dough-like mass.^[19] This step incorporates the primary chemical components, ensuring uniform distribution before further processing.^[19] The lacquer is then extruded through a die to form long cylindrical cords, which are subsequently cut into short cylindrical pellets using die-face cutting blades. These pellets are introduced into a tumbling apparatus containing hot water, where mechanical agitation causes them to roll against each other and the container walls. The hot water gelatinizes the outer surface of the pellets, softening the nitrocellulose and promoting the formation of smooth, spherical granules with diameters typically ranging from 0.01 to 0.05 inches (0.25 to 1.27 mm).^[3]^[20] This spherulization step is critical for achieving the characteristic ball geometry, which enhances handling and burning uniformity. For double-base variants, the spherical granules undergo surface impregnation with nitroglycerin in an aqueous medium following spherulization. Some types are further flattened via roller pressing to enhance burn characteristics. Following spherulization, additional water is added to produce a free-flowing aqueous slurry, which is screened to separate oversized and undersized particles for rework or discard. The slurry undergoes washing to extract residual ethyl acetate solvent, followed by drying to remove moisture and solidify the spheres. The dried granules are then coated with deterrents, such as dibutyl phthalate or nitroguanidine, to control burn rate, and glazed with graphite to improve flow and reduce static. Solvent recovery occurs via distillation during washing and drying, minimizing waste.^[19]^[6] Wastewater generated throughout the process, particularly from tumbling, washing, and screening, contains byproducts including ethyl acetate, nitrocellulose fines, nitroglycerin (if added post-spherulization), and deterrents like nitroguanidine. This effluent requires biological treatment to degrade organic components and remove suspended solids before discharge or recycling, ensuring environmental compliance.^[21] The overall batch process is designed for efficiency, with solvent removal achievable in a few hours.^[22]

Safety and Efficiency Advantages

The manufacturing process of ball propellant, particularly its aqueous tumbling stage, substantially enhances safety by conducting most operations underwater, which prevents the generation of dry combustible dust and thereby minimizes the risk of dust explosions during handling and processing.^[5] This wet environment allows for the safer management of large batches, as the material remains submerged, reducing ignition hazards compared to dry processing methods in traditional extrusion techniques.^[6] Efficiency gains are evident in the rapid production timeline, with a typical batch of approximately 40,000 pounds completed in about 40 hours, in contrast to the two weeks required for extruded propellants.^[3] This accelerated cycle supports scalability, particularly during wartime demands, enabling quick adjustments to output without extensive retooling.^[3] Additionally, the process incurs lower energy and equipment costs due to reduced water and energy consumption relative to extrusion methods, while solvent use—primarily ethyl acetate—is minimized through efficient distillation and recovery, avoiding the higher residual solvent issues in dry extrusion.^[6]

Physical Properties

Grain Geometry and Density

Ball propellant grains are characterized by their distinctive spherical geometry, which distinguishes them from other smokeless powder forms such as extruded or flake types. This uniform spherical shape, typically with diameters ranging from 0.4 to 0.71 mm, enables excellent flowability during handling and loading processes.^[23] The spherical configuration allows the grains to roll easily, reducing bridging or clumping that can occur with irregular shapes, thereby facilitating precise volumetric metering in automated reloading equipment.^[24] The density of ball propellant grains plays a critical role in determining the charge weight and overall storage volume for ammunition production. Bulk densities generally fall within 0.5 to 1.0 g/cm³, while the specific gravity ranges from 1.2 to 1.6 g/cm³, allowing for compact packing that optimizes space efficiency without compromising performance.^[25] Higher densities within this range contribute to greater energy per unit volume, influencing the amount of propellant required per cartridge and the volumetric requirements for bulk storage.^[26] The spherical geometry of ball propellant also affects initial combustion through its consistent surface area, promoting uniform ignition compared to irregular grain shapes. Unlike angular or oblong grains, which exhibit variable surface-to-volume ratios leading to inconsistent ignition times, the uniform spheres ensure even exposure to the igniter flame, resulting in more predictable combustion onset across the charge.^[27] This uniformity is achieved during the manufacturing tumbling process, where the grains solidify into spheres in a solvent suspension.^[26]

Burn Characteristics and Stability

Ball propellants exhibit progressive burning behavior, where the combustion rate increases as the grain is consumed, primarily due to the incorporation of deterrents such as dibutyl phthalate or other ester-based compounds impregnated into the spherical grains. These deterrents slow the initial surface burn rate while allowing acceleration in later stages, promoting consistent pressure buildup in the firearm chamber. This progressivity is enhanced by the uniform spherical geometry, which maintains predictable surface area exposure during combustion.^[28]^[29] The flame temperatures generated by ball propellants during combustion typically range from 3,200 to 3,300°F, which is slightly lower than many extruded smokeless powders and contributes to reduced barrel erosion over extended use.^[30] Standard ball propellants demonstrate moderate temperature sensitivity, with muzzle velocity variations of approximately 1-2% per 10°F change in ambient conditions, though double-base formulations can exhibit higher shifts up to 2.5% over a 50°F range due to the influence of nitroglycerin content on burn rate. In contrast, modern variants like Winchester's StaBALL series incorporate advanced stabilization techniques to achieve temperature insensitivity, limiting velocity changes to less than 1% across extreme ranges from -40°F to 140°F, making them suitable for variable environmental applications.^[31]^[32]^[33] Long-term stability of ball propellants is robust, with a shelf life extending up to 50 years or more under proper storage conditions such as cool, dry environments away from contaminants. Deterioration is primarily assessed by monitoring acidity levels, as decomposition of nitrate esters produces acidic byproducts like nitric acid, which can be detected through odor, color changes, or chemical analysis of stabilizer depletion; such indicators suggest potential instability requiring disposal.^[34]^[35]^[36]

Performance and Applications

Ballistic Performance Metrics

Ball propellants contribute to efficient conversion of chemical energy into projectile kinetic energy. This energy profile supports muzzle velocities reaching up to 1,200 m/s in small arms configurations, particularly with optimized loads in rifle cartridges.^[37] A key advantage of ball propellants is their clean-burning nature, which results in minimal residue accumulation in the barrel and chamber after firing.^[38] Flash-suppressed variants further enhance performance by significantly reducing muzzle flash, minimizing visible signature and overpressure effects.^[38] In terms of pressure dynamics, ball propellants exhibit a more gradual pressure rise compared to flake powders, owing to their spherical geometry and progressive burn characteristics.^[39] This allows for higher charge densities—often exceeding 0.9 g/cm³—while maintaining pressures within safe operational limits, typically below 400 MPa for small arms.^[40] The burn rate, which influences these curves, is detailed in the physical properties section.

Military and Civilian Uses

Ball propellant plays a central role in military ammunition, powering over 99% of U.S. small arms cartridges up to 20mm caliber.^[1] It is the primary propellant for key NATO-standard rounds, including the 5.56mm NATO cartridge variants such as the M193 ball, M855 armor-piercing, M196 tracer, and M856 tracer, typically loaded with WC 844 or similar formulations (with modern REACH-compliant replacements like SMP® 835 and SMP® 842) for consistent performance in rifles like the M16 and M4.^[41] Similarly, in 9mm Parabellum ammunition, ball propellant is used in the M882 NATO ball round, employing clean-burning types like WPR® 289 to minimize flash and residue in pistols and submachine guns.^[42] With over 200 variants tailored for small to medium calibers ranging from 5.56mm to 30mm, ball propellant supports diverse applications in infantry weapons, machine guns, and crew-served systems, enabling high-volume production and reliable ballistics across global militaries. In civilian applications, ball propellant has been available for handloading since 1960, allowing reloaders to create customized ammunition for firearms. Powders like H110, a spherical formulation from Hodgdon, are widely used in magnum handgun cartridges such as .44 Magnum, .454 Casull, and .357 Magnum, providing high velocities and accuracy in revolvers and semi-automatics when paired with magnum primers for full ignition.^[43] For rifle reloading, BL-C(2) serves as a versatile option, derived from military surplus and suited for cartridges like .308 Winchester and .30-06 Springfield, offering medium burn rates for varmint hunting, target shooting, and long-range loads with reduced barrel fouling.^[44] These powders' spherical geometry facilitates precise metering in progressive presses, supporting the handloading community's demand for tailored performance since their commercial introduction. Industrial uses of ball propellant are more limited but include shotshell loading, where formulations like Winchester 572 and H110 optimize patterns and velocities in 12-gauge and .410-bore shells for hunting and sporting clays.^[45] It also finds niche applications in certain pyrotechnic devices requiring controlled, low-residue burns, though black powder remains more common in fireworks.^[46]

Comparisons with Other Propellants

Versus Extruded Propellants

Ball propellants exhibit superior metering performance compared to extruded propellants, primarily due to their uniform spherical geometry, which ensures consistent flow through volumetric dispensers and minimizes variations in charge weights. This shape allows for greater volumetric accuracy in reloading operations, reducing the need for precise weighing and enhancing overall efficiency. In contrast, extruded stick or cylindrical propellants are more susceptible to breakage during handling and metering, leading to irregular grain lengths that can cause inconsistent dispensing and potential over- or under-charges.^[47]^[48] Regarding storage and long-term stability, ball propellants demonstrate greater resistance to degradation than extruded types, attributed to their compact spherical form that limits overall surface area exposure to environmental factors such as moisture and oxygen. This design contributes to a longer shelf life, with ball powders maintaining ballistic consistency over extended periods without significant loss of performance. Extruded propellants, however, possess a higher effective surface area due to their elongated structure, making them more vulnerable to chemical breakdown and physical crumbling, which can compromise reliability during prolonged storage.^[30]^[49] Ball propellants are generally more temperature-sensitive than extruded propellants, leading to greater velocity variations in extreme conditions, though advancements have mitigated this in modern formulations.^[50] In terms of barrel longevity, ball propellants generally cause less erosion than extruded propellants, owing to their lower flame temperatures during combustion. Ball powders typically burn at 3,200–3,300°F, producing reduced heat stress on the barrel throat and rifling compared to extruded powders, which can reach up to 3,400°F. This thermal advantage helps preserve barrel accuracy and extends service life, particularly in high-volume shooting applications, while extruded propellants' higher temperatures accelerate wear through increased material ablation.^[30]

Versus Flake and Sheet Propellants

Ball propellant, characterized by its spherical grains, differs from flake and sheet propellants—flat, irregular shapes often used in faster-burning applications—in several key performance aspects. Regarding ignition, ball propellants are generally harder to ignite due to their uniform spherical geometry and deterrent coatings, often requiring higher-energy primers such as magnum types to ensure reliable combustion, whereas flake propellants ignite more readily owing to their greater initial surface area exposure.^[51]^[52] In terms of flash and fouling, ball propellants, typically double-base formulations, tend to produce brighter muzzle flash and increased residue compared to many flake propellants, which often burn cleaner in lighter loads; this is attributed to the nitroglycerin content in double-base powders contributing to higher flame temperatures and unburnt particles.^[53]^[51] For versatility, ball propellants excel in progressive burning profiles suitable for magnum cartridges, where chemical modifications allow controlled energy release for higher velocities in large cases like those in 6.5 PRC or .300 Winchester Magnum, while sheet and flake propellants are better suited for quick, high-pressure pistol loads such as 9mm or .45 ACP, providing rapid combustion without excessive pressure spikes.^[3]^[30]

Advantages, Disadvantages, and Safety

Key Benefits

Ball propellants offer significant advantages in manufacturing scalability, enabling high-volume production to meet wartime demands. During World War II, government-owned facilities like the Badger Ordnance Works produced over 109 million pounds of small arms powder and 148 million pounds of cannon powder using ball propellant processes, leveraging rapid construction of specialized lines and a workforce peaking at over 12,000.^[54] This scalability stems from the solvent-based spherical grain formation, which supports efficient, continuous processing in large-scale plants compared to more labor-intensive extruded methods. The spherical geometry of ball propellants enhances uniform metering during loading, minimizing charge weight variations and improving overall load consistency. This flowability allows precise volumetric dispensing through automated measures, reducing inconsistencies that can affect ballistic performance in extruded powders.^[50] Modern temperature-stable variants, such as Winchester StaBALL 6.5, further exemplify these benefits by delivering consistent velocities across extreme hot or cold conditions, with minimal deviation to ensure reliable performance in diverse environments.^[33] This stability, combined with precise metering, results in low standard deviations in velocity and pressure, making it suitable for precision applications like the 6.5 Creedmoor cartridge.^[33]

Limitations and Drawbacks

Ball propellants, particularly non-StaBALL variants, demonstrate notable temperature sensitivity, resulting in substantial velocity variations under extreme conditions. Unlike temperature-stable formulations such as StaBALL powders, conventional ball types can exhibit significant velocity shifts across temperature extremes, impacting ballistic consistency in varying environmental conditions.^[50]^[55]^[32] Compared to single-base powders, ball propellants—typically double-base compositions—generate higher levels of fouling and muzzle flash due to their inclusion of nitroglycerin, which elevates combustion temperatures and residue production. This increased fouling accelerates barrel wear and requires more frequent cleaning to maintain performance.^[56]^[31] In certain rifle loads, especially those with lower charge densities, ball propellants can display position sensitivity arising from the spherical grains' tendency to settle unevenly within the cartridge. This settling alters the ignition and burn pattern based on the round's orientation, potentially leading to inconsistent velocities.^[57]

Handling and Storage Guidelines

Ball propellant, a form of smokeless powder, requires careful storage to maintain its stability and prevent degradation or accidental ignition. It should be kept in a cool, dry environment at temperatures below 70°F (21°C) and relative humidity around 50%, ideally in original Department of Transportation (DOT)-approved shipping containers to minimize exposure to air and contaminants.^[58]^[59] Storage areas must be well-ventilated, away from direct sunlight, heat sources, electrical equipment, and incompatible materials such as acids, oxidizers, or alkalis, with quantities limited according to NFPA 495 guidelines—for example, no more than 20 pounds in residences without additional fire-resistant enclosures.^[60]^[61] Periodic inspection for signs of deterioration, such as an acidic odor or reddish-brown residue, is recommended every 5-10 years or sooner if exposed to suboptimal conditions, as this indicates chemical instability that could lead to spontaneous combustion.^[60]^[61] Handling ball propellant demands precautions to avoid ignition risks and health hazards from its components, primarily nitrocellulose. Direct contact can cause eye and skin irritation, so users should wear safety glasses with side shields, impermeable gloves, and flame-retardant clothing, washing affected areas immediately with water if exposure occurs.^[59]^[58] To prevent sparks or static electricity buildup—particularly during pouring or transfer—ground all equipment, avoid mechanical shock, and work in low-humidity areas, as static discharge can ignite the highly flammable powder.^[59]^[61] Spills should be cleaned promptly without generating dust, and no smoking or open flames are permitted nearby. For disposal, especially of deteriorated ball propellant, follow Environmental Protection Agency (EPA) guidelines for flammable hazardous waste, which classify unstable smokeless powders as D001 characteristic wastes. Neutralize acidic residues if present by submerging in water before disposal, then burn small quantities (no more than 1 pound per pile, spread in shallow layers) in an isolated, open area using a long ignition train to avoid flashover, ensuring compliance with local fire regulations.^[60]^[58] Alternatively, for intact nitrocellulose-based material, professional recycling programs may recover components, but deteriorated powder must not be landfilled or dumped to prevent environmental contamination.^[58]

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General Dynamics Ordnance and Tactical Systems manufactures a wide variety of solid propellants that are qualified for commercial automotive and military ...
[41]
Tech blog: Powder grain shapes - Vihtavuori
Apr 24, 2018 · Flake and ball grains are degressive; the total powder surface area and pressure are at their peak at ignition, decreasing as the combustion ...
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Internal Ballistics - Fr. Frog's
The grains of modern smokeless propellant powders are made in various sizes and shapes to give the best results in the firearm they are designed to be used in.
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[PDF] MILITARY BALL POWDER PROPELLANTS
St. Marks Powder is recognized as the worldwide leader in BALL POWDER® Propellant technology for small, medium and specific large caliber applications.
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[PDF] Small Caliber Propellant Solutions for the US Military
May 19, 2010 · Marks BALL POWDER ® Propellant used in the 9mm NATO M882 cartridge is designed to be clean burning with reduced flash. 9mm NATO M882. Jonathan ...
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Buy H110® Shotshell and Pistol Powder - Hodgdon Powder Co
H110 is the spherical powder that screams "no wimps, please!", delivering top velocities with great accuracy in 44 Magnum, 454 Casull, 475 Linebaugh and the ...Missing: handloading | Show results with:handloading
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Buy Hodgdon BL-C(2)® Rifle Powder
A spherical powder, BL-C(2) began as a military powder used in the 7.62 NATO and naturally has applications for 308 Winchester.Missing: civilian H110 history 1960<|control11|><|separator|>
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Winchester 572 - Hodgdon Powder Co
Buy Winchester 572 reloading powder, a ball powder strategically designed to optimize a myriad of shotshell and handgun loads ... Hodgdon Powder Co. Shop.
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Characterization of display pyrotechnic propellants: Burning rate
Jul 5, 2017 · Pyrotechnic propellants are employed to create specific effects such as a loud sound, bright sparks, smoke, or colored illuminating flames.
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Metering Quality of Different Types of Powders - Lee Precision, Inc.
Mar 21, 2019 · These types of powder meter better. Spherical (ball) powders do this best. Small grain extruded flake powders are almost as good. Followed by ...
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[PDF] Complete Load Guide Edition 8.0 - Hodgdon Powder Company
The guide covers getting started, reloading basics including examining cases, lubing, sizing, priming, powder charge, bullet seating, and when to crimp.
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[PDF] Engineering Design Handbook. Ballistic Series. Interior ... - DTIC
The present handbook deals with the interior ballistics of guns. This handbook, Interior Ballistics of Guns, presents fundamental data, fol- lowed by ...
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M-16: A Bureaucratic Horror Story - The Atlantic
Jun 1, 1981 · The new ball powder was inherently dirtier, and it burned longer; it was still burned when the gas port opened, so it burned into the gas tube.
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[PDF] Enhancement of Semiconductor Bridge Initiators for Ignition of Large ...
The ball powder is harder to ignite than black powder. In Figure 12, the ignition and rapture of the black powder booster occurred in less than a ...
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Method of reducing the muzzle flash when firing firearms loaded ...
When the powder is double-base powder, the flash-reducing agent can be added ... A method of reducing the muzzle flash formed when firing firearms loaded with ...
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[PDF] The World War II Ordnance Department's Government-Owned ...
Badger produced Ball Powder Propellant, Rocket Propellant and. Smokeless Powder for the Vietnam conflict. Production continued from January 1966 through January ...
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There's More to Gunpowder Than You Think - Guns and Ammo
Jan 4, 2019 · Flake propellant is nothing more than a very short cylinder. Ball propellant is cut as a cylinder that is as long as it is wide. These cylinders ...<|control11|><|separator|>
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[PDF] Temperature Sensitivity of Aircraft Cannon Propellants - DTIC
in rolled ball propellant under ignition impact conditions (Reference 16). Figure 9 shows the temperature sensitivity data for the rolled double base ball ...
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"Smokeless Powder" from Tactical and Technical Trends - Lone Sentry
Double-base powders are rendered flashless by the addition in the composition of small proportions of inorganic salts. When nitro-cellulose powder is treated to ...
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[PDF] Accurate Smokeless Powder - Textfiles
Jan 7, 2003 · ... powder position sensitivity. 2460 A fast burning, double base, ball-type rifle powder that is a slower derivative of the 2230 powder.
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### Summary of Ball Powder Propellant Safety Data Sheet
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[PDF] Propellant, Ball Powder - SAFETY DATA SHEET
This product is composed of twelve different chemical components. Acute ... blood vessels and drop in blood pressure (nitroglycerin), reproductive ...
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Storage & Handling - Alliant Powder
10-3.6 Smokeless propellants shall be stored in shipping containers specified by U. S. Department of Transportation Hazardous Materials Regulations. 10-3.7 ...
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[PDF] SMOKELESS POWDER - Accurate Shooter
SMOKELESS. POWDER. Properties & Storage. 11 Mile Hill Road, Newtown, CT 06470-2359 www.saami.org. Page 2. Ammunition handloading has become increasingly popular ...