Even wearing double hearing protection (earplugs and muffs), some shooters have experienced hearing loss from high volume or long term shooting,^[5] probably due to the shockwaves from muzzle blasts propagating though the sinuses and facial bone structures.^{[citation needed]} The noise levels experienced are often increased when firing indoor^[6] or in other confined spaces. Sound suppressors are increasingly commonly used by shooters to reduce the concussion and thereby prevent hearing loss, but are not always suitable for either legal or technical reasons. Suppressors can either be difficult or illegal to obtain in some jurisdictions, while a concussion reduction device is normally not classified as such. Concussion reduction devices also typically don't have the problem of introducing the extra amount of mirage as a suppressor does, since suppressors work by absorbing heat from the burnt gunpowder. The extra mirage can make accurate aiming difficult, especially on precision targets at long range.

A muzzle shroud can also increase comfort compared to a muzzle brake while shooting prone by preventing dust to kick up from the ground.^[7]

Sound waves are semi-directional. They consist of both Point- and Line-wave propagation. The projectile emanates mostly line-propagation properties after leaving the barrel. At the moment that the projectile is exiting the barrel it produces a mainly point-biased wave generation. (This is largely due to the shock waves traveling forward along the interior of the barrel, thus preventing any backward travel from the projectile into the barrel.) Sound waves travel in an ever-expanding bubble emanating from the muzzle when the propellant gases are traveling at supersonic speeds. This is called the "muzzle blast." Except in extremely low pressure loads, the exiting propellant gasses generate much higher sound pressure levels (dBa) than any other aspect of the weapon firing. (e.g., hammer, sear, bolt, supersonic flight signature, etc.) The supersonic "ballistic crack" is typically 136-138 dB, whereas "muzzle blast" may reach 168 dB. By encircling the muzzle, the shroud funnels and focuses the sound waves along the projectile flight axis, away from the shooter. This alone can partially protect the shooter from 12 to 18 dB of blast returning to the shooter's ears.

United States edit

In the United States, the ATF has ruled that since the sound waves are not dampened and are metered at the same levels at two measuring points (1 m (3.3 ft) to the left and 0 m in front of the muzzle and 1 m (3.3 ft) left and 5 m (16 ft) forward of the muzzle) this is not a sound suppressing device. The only action which a muzzle shroud performs is shielding the area directly behind the muzzle from the worst blast pressures. Muzzle brakes direct the escaping gases rearward toward the shooter, thus increasing blast pressure directed toward the operator's ears. The same principle that lessens felt recoil also acts to enhance the sound levels reaching the shooter. Some of the muzzle brakes designed for heavy-caliber rifles (.338 Lapua, .408 CheyTac, .50 BMG) incorporate "blast shields" projecting laterally from the sides of the muzzle crown. These reflect sound waves traveling rearward via the muzzle brake blast chambers. These small leaves, however, do not fully enclose the muzzle diameter, and so block only the worst blast path, while allowing the majority of escaping gases to circumvent the shield by traveling around them, still reaching the shooter's ears, potentially causing hearing damage^{[citation needed]}.

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  An MG 34 with a conical muzzle shroud.
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  The Lee Enfield Jungle Carbine (Rifle No. 5 Mk I) with a conical flash suppressor (muzzle shroud).
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  Front sight extensions on an ISSF air rifle are effectively muzzle shrouds used to increase the sight radius, aiding in precise aiming with iron sights.
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  A Lewis gun with a muzzle shroud.

• Muzzle booster
• Jet blast deflector