The .223 Remington, also known as 223 Remington by SAAMI and 223 Rem. by the C.I.P., (pronounced "two-two-three") is a rimless, bottlenecked, centerfire intermediate cartridge. It was developed in 1957 by Remington Arms and Fairchild Industries for the U.S. Continental Army Command of the United States Army as part of a project to create a small-caliber, high-velocity firearm. Firing a projectile, the .223 Remington is considered one of the most popular common-use cartridges and is used by a wide range of semi-automatic and manual-action rifles.
The development of the cartridge, which eventually became the .223 Remington, was linked to the creation of a new small-caliber, high-velocity (SCHV) combat rifle. Work on a rifle and cartridge to meet the requirements of the U.S. Continental Army Command (CONARC) began in 1957. Fairchild Industries, Remington Arms, Winchester, and several engineers (including Eugene Stoner of ArmaLite, who was invited to scale down the AR-10 (7.62ÃÂ51mm NATO) design). contributed.
CONARC ordered rifles to test. Stoner and Sierra Bullet's Frank Snow began work on the .222 Remington cartridge. Using a ballistic calculator, they determined that a 55-grain bullet would have to be fired at 3,300 ft/s to achieve the 500-yard performance necessary.
Robert Hutton (technical editor of Guns and Ammo magazine) started the development of a powder load to reach the 3,300 ft/s goal. He used DuPont IMR4198, IMR3031, and an Olin powder to work up loads. Testing was done with a Remington 722 rifle with a 22" Apex barrel.
During a public demonstration, the round successfully penetrated the US steel helmet as required, but testing also showed chamber pressures to be too high.
Stoner contacted both Winchester and Remington about increasing the case capacity. Remington created a larger cartridge called the .222 Special. This cartridge is loaded with DuPont IMR4475 powder.
During parallel testing of the T44E4 (future M14) and the ArmaLite AR-15 in 1958, the T44E4 experienced 16 failures per 1,000 rounds fired compared to 6.1 for the ArmaLite AR-15. Because of several different .222 caliber cartridges that were being developed for the SCHV project, the .222 Special was renamed .223 Remington. In May 1959, a report was produced stating that five- to seven-man squads armed with ArmaLite AR-15 rifles have a higher hit probability than 11-man squads armed with the M14 rifle. At an Independence Day picnic, Air Force General Curtis LeMay tested the ArmaLite AR-15 and was very impressed with it. He ordered a number of them to replace M2 carbines that were in use by the Air Force. In November of that year, testing at Aberdeen Proving Ground showed the ArmaLite AR-15 failure rate had declined to 2.5/1,000, resulting in the ArmaLite AR-15 being approved for more extensive trials.
In 1961, marksmanship testing compared the AR-15 and M14; 43% of ArmaLite AR-15 shooters achieved Expert, while only 22% of M14 rifle shooters did. Le May ordered 80,000 rifles. In July 1962, operational testing ended with a recommendation for the adoption of the ArmaLite AR-15 rifle chambered in .223 Remington. In September 1963, the .223 Remington cartridge was officially accepted and named "Cartridge, 5.56 mm ball, M193". The following year, the ArmaLite AR-15 was adopted by the United States Army as the M16 rifle, and it would later become the standard U.S. military rifle. The specification included a Remington-designed bullet and the use of IMR4475 powder, which resulted in a muzzle velocity of 3,250 ft/s and a chamber pressure of 52,000 psi.
In the spring of 1962, Remington submitted the specifications of the .223 Remington to the Sporting Arms and Ammunition Manufacturers' Institute (SAAMI). In December 1963, Remington introduced its first rifle chambered for .223 Remington a Model 760 rifle.
The .223 Remington has a 1.87 mL (28.8 gr H<sub>2</sub>O) cartridge case capacity.
.223 Remington maximum CIP cartridge dimensions. All sizes in millimeters (mm).
Americans would define the shoulder angle at alpha/2 = 23 degrees. The common rifling twist rate for this cartridge is 305 mm (1 in 12 in), 6 grooves, ÃÂ lands = , ÃÂ grooves = , land width = and the primer type is small rifle.
According to the official CIP rulings, the .223 Remington can handle up to P<sub>max</sub> piezo pressure. In CIP-regulated countries, every rifle cartridge combination has to be proofed at 125% of this maximum CIP pressure to certify for sale to consumers. This means that .223 Remington chambered arms in CIP-regulated countries are proof tested at PE piezo pressure. This is equal to the NATO maximum service pressure guideline for the 5.56ÃÂ45mm NATO cartridge.
The SAAMI pressure limit for the .223 Remington is set at , piezo pressure. Remington submitted .223 Remington specifications to SAAMI in 1964.
In 1980, the .223 Remington was transformed into a new cartridge and designated 5.56ÃÂ45mm NATO (SS109 or M855).
The external dimensional specifications of .223 Remington and 5.56ÃÂ45mm NATO brass cases are nearly identical. The cases tend to have similar case capacity when measured (case capacities have been observed to vary by as much as 2.6 grains (0.17 ml)), although the shoulder profile and neck length are not the same and 5.56ÃÂ45mm NATO cartridge cases tend be slightly thicker to accommodate higher chamber pressures. When hand-loaded, care is taken to look for pressure signs as 5.56ÃÂ45mm NATO cases may produce higher pressures with the same type of powder and bullet as compared to .223 Remington cases. Sierra provides separate loading sections for .223 Remington and 5.56ÃÂ45mm NATO and also recommends different loads for bolt-action rifles as compared to semiautomatic rifles.
Remington submitted the specifications for the .223 Remington cartridge in 1964 to SAAMI. The original pressure for the .223 Remington was 52,000 psi with DuPont IMR Powder. A higher pressure of resulted from the change from IMR to Olin Ball powder. The official name for .223 Remington in the US Army is cartridge 5.56x45mm ball, M193. If a 5.56ÃÂ45mm NATO cartridge is loaded into a chamber intended to use .223 Remington, the bullet will be in contact with the rifling and the forcing cone is very tight. This generates a much higher pressure than .223 Remington chambers are designed for.
Chamber pressures obtained using different methods are not comparable. The pressure limits for .223 Rem and 5.56ÃÂ45mm NATO are very similar, if using similar measurement methodologies.
The .223 Remington and 5.56ÃÂ45mm NATO barrel chamberings are not the same according to Clymer, with the 5.56 NATO chamber having generally slightly larger dimensions. A brochure from "Forster Products" claims that while the headspace gauge for .223 Rem is 1.4636/1.4666/1.4696 for Go/NoGo/Field, the gauge is 1.4636/1.4736 for Min/Max on 5.56 NATO. The brochure goes on to claim that this could mean a premature contact with rifling with 5.56 ammunition if fired from a .223 chamber. However, the 2025 SAAMI specification for the headspace dimension on .223 Rem is the same as what Forster claimed for 5.56 NATO: 1.4636 to 1.4736. In any case, the premature contact allegation is likely not based on headspace differences, but on the lede length and angle difference between the two chambers, with 5.56 NATO having a shallower and longer lede.
By observation, 5.56ÃÂ45mm NATO ammunition is not as accurate as .223 Remington in many of the AR-type rifles extant, even with the same bullet weight. The .223 Wylde chamber specification developed by Bill Wylde solves this problem by using the external dimensions and lead angle as found in the military 5.56ÃÂ45mm NATO cartridge and the 0.224 inch freebore diameter as found in the civilian SAAMI .223 Remington cartridge. It was designed to increase the accuracy of 5.56ÃÂ45mm NATO ammunition to that of .223 Remington. Other companies also have chamber designs that increase 5.56ÃÂ45mm NATO accuracy. (The "lower accuracy" observation for 5.56 chambers running .223 ammunition has not been reproduced with newer tests.)
Andrew of LuckyGunner LLC has collected 8 different chamber dimensions from various reamer companies, including .223 Rem, .223 Wylde, and 5.56. He also emphasizes that manufacturing differences will make each actual chamber dimensionally different from others. In addition, he tested 5.56 NATO ammunition in .223 Rem chambers and failed to find dangerous levels of pressure increase.
NATO chose a 178-mm (1-in-7) rifling twist rate for the 5.56ÃÂ45mm NATO chambering. The SS109/M855 5.56ÃÂ45mm NATO ball cartridge requires a minimum 228 mm (1-in-9) twist rate, while adequately stabilizing the longer NATO L110/M856 5.56ÃÂ45mm NATO tracer projectile requires an even faster 178 mm (1-in-7) twist rate.
The table contains some estimated pressures based on normal proofing practice and on the known increases in pressure caused by bullet setback (which is a similar occurrence with regard to pressure). The proof pressure of M197 is 70,000 psi.
The following table shows the differences in nomenclature, rifling, throating, and normal, maximum, and safe pressures:
Key to peak pressure measurement methods:
Notes:
Barrel length helps determine a specific cartridge's muzzle velocity. A longer barrel typically yields a greater muzzle velocity, while a shorter barrel yields a lower one. The first AR-15 rifles used a barrel length of 20".
The .223 Remington has become one of the most popular cartridges. It is used in a wide range of semiautomatic and manual-action rifles and even handguns, such as the Colt AR-15, Ruger Mini-14, Remington Model 700. For example, the cartridge has become widely used in the US, significantly reducing the prevalence of other similar .22 caliber center-fire varmint rifle cartridges.
It is commercially loaded with 0.224-inch (5.7 mm) diameter jacketed bullets, with weights ranging from 35 to 85 grains (2.27 to 5.8 g), with the most common loading by far being 55 gr (3.6 g). Ninety-grain and 95-grain (6.2 g) Sierra Matchking bullets are available for reloaders.