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{{Main|Shell (projectile)}} |
{{Main|Shell (projectile)}} |
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| − | [[File:Unexploded shell in the cathedral in Genoa (Italy).jpg|thumb|right|Unexploded British naval 15-inch shell in |
+ | [[File:Unexploded shell in the cathedral in Genoa (Italy).jpg|thumb|right|Unexploded British naval 15-inch shell in Genoa Cathedral, fired in 1941, with its armor-piercing cap on the floor to the left. The ballistic cap is absent.]] |
[[File:BL15inchAPMkXXIIBNTShell1943Diagram.jpg|thumb|right|<center>Internal structure of British World War II naval [[BL 15 inch Mk I naval gun|15-inch]] APCBC shell</center>]] |
[[File:BL15inchAPMkXXIIBNTShell1943Diagram.jpg|thumb|right|<center>Internal structure of British World War II naval [[BL 15 inch Mk I naval gun|15-inch]] APCBC shell</center>]] |
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[[File:Battleship-bullet.JPG|thumb|right|<center>Battleship shells 46cm,40cm,36cm;World War II </center>]] |
[[File:Battleship-bullet.JPG|thumb|right|<center>Battleship shells 46cm,40cm,36cm;World War II </center>]] |
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| − | The '''armour-piercing capped ballistic cap''' ('''APCBC''') is a type of [[armor-piercing shell]] introduced in the 1930s. |
+ | The '''armour-piercing capped ballistic cap''' ('''APCBC''') is a type of [[armor-piercing shell]] introduced in the 1930s. |
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==Development== |
==Development== |
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| − | The APCBC munition type was an evolutionary development of the early war [[armour-piercing capped]] (APC) shell, itself an evolution of the more basic AP (armor piercing or solid shot) and APHE (armor piercing high explosive) shell types. With respect to armored land warfare, the primary intended function of both AP and APHE shell types was to penetrate an enemy armored vehicle and incapacitate the vehicle and crew by internal explosion (in the case of APHE) or fragmentation/ricochet (in the case of AP rounds). |
+ | The APCBC munition type was an evolutionary development of the early war [[armour-piercing capped]] (APC) shell, itself an evolution of the more basic AP (armor piercing or solid shot) and APHE (armor piercing high explosive) shell types. With respect to armored land warfare, the primary intended function of both AP and APHE shell types was to penetrate an enemy armored vehicle and incapacitate the vehicle and crew by internal explosion (in the case of APHE) or fragmentation/ricochet (in the case of AP rounds). |
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As the war lengthened, target armor became progressively thicker (and sloped) as new tank designs emerged, and early war AP and APHE became progressively less effective. The initial response to this thickening in armor had been to increase the muzzle velocity in newly developed anti-tanks guns. However, it was found that steel shot tended to shatter on impact at velocities upward of about 823 m/s (2700 feet/second).<ref name="flamesofwar1">{{cite web|url=http://www.flamesofwar.com/hobby.aspx?art_id=836 |title=Hobby |publisher=Flamesofwar.com |accessdate=2010-06-12}}</ref><ref name="junobeach1">{{cite web|url=http://www.junobeach.org/e/4/can-tac-art-atp-e.htm |title=Juno Beach Centre - Anti-Tank Projectiles |publisher=Junobeach.org |accessdate=2010-06-12}}</ref> |
As the war lengthened, target armor became progressively thicker (and sloped) as new tank designs emerged, and early war AP and APHE became progressively less effective. The initial response to this thickening in armor had been to increase the muzzle velocity in newly developed anti-tanks guns. However, it was found that steel shot tended to shatter on impact at velocities upward of about 823 m/s (2700 feet/second).<ref name="flamesofwar1">{{cite web|url=http://www.flamesofwar.com/hobby.aspx?art_id=836 |title=Hobby |publisher=Flamesofwar.com |accessdate=2010-06-12}}</ref><ref name="junobeach1">{{cite web|url=http://www.junobeach.org/e/4/can-tac-art-atp-e.htm |title=Juno Beach Centre - Anti-Tank Projectiles |publisher=Junobeach.org |accessdate=2010-06-12}}</ref> |
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The cap transferred energy from the tip of the shell to the sides of the projectile, thereby helping to reduce shattering. In addition, the cap appeared to improve penetration of sloped armor by deforming, spreading and “sticking” to the armor on impact and thereby reducing the tendency of the shell to deflect at an angle. However, the cap structure of the APC shell reduced the aerodynamic efficiency of the round with a resultant reduction in accuracy and range'<ref name="flamesofwar1"/><ref name="junobeach1"/> |
The cap transferred energy from the tip of the shell to the sides of the projectile, thereby helping to reduce shattering. In addition, the cap appeared to improve penetration of sloped armor by deforming, spreading and “sticking” to the armor on impact and thereby reducing the tendency of the shell to deflect at an angle. However, the cap structure of the APC shell reduced the aerodynamic efficiency of the round with a resultant reduction in accuracy and range'<ref name="flamesofwar1"/><ref name="junobeach1"/> |
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| − | To address the reduction in accuracy caused by the addition of a cap to an AP round, a second cap or cover was introduced in the design of APCBC munition. This involved fitting a streamlined ballistic cap over the APC, thereby increasing accuracy, reducing in-flight loss of velocity and increasing penetration.<ref>{{cite web|url=http://members.tripod.com/~nigelef/anti-tank.htm |title=Anti-Tank |publisher=Members.tripod.com |date=1943-03-06 |accessdate=2010-06-12}}</ref> |
+ | To address the reduction in accuracy caused by the addition of a cap to an AP round, a second cap or cover was introduced in the design of APCBC munition. This involved fitting a streamlined ballistic cap over the APC, thereby increasing accuracy, reducing in-flight loss of velocity and increasing penetration.<ref>{{cite web|url=http://members.tripod.com/~nigelef/anti-tank.htm |title=Anti-Tank |publisher=Members.tripod.com |date=1943-03-06 |accessdate=2010-06-12}}</ref> |
| ⚫ | Early WWII-era uncapped AP projectiles fired from high-velocity guns were able to penetrate about twice their caliber at close range (100 m). At longer ranges (500-1,000 m), this dropped to 1.5-1.1 calibers due to the poor ballistic shape and higher drag of the smaller-diameter early projectiles. Later in the conflict, APCBC fired at close range (100 m) from large-caliber, high-velocity guns (75–128 mm) were able to penetrate a much greater thickness of armor in relation to their caliber (2.5 times) and also a greater thickness (2-1.75 times) at longer ranges (1,500-2,000 m). Comparative testing of British [[Ordnance QF 17 pounder]] APCBC rounds fired into captured German [[Panther tank]]s indicated the APCBC munitions were more accurate than late war [[armour-piercing discarding sabot]] (APDS) shot.<ref>U.S. Army Firing Test No.3, U.S. Army Firing Tests conducted August 1944 by 12th U.S. Army Group at Isigny, France. Report of tests conducted during 20–21 August 1944.</ref> |
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| ⚫ | Early WWII-era uncapped AP projectiles fired from high-velocity guns were able to penetrate about twice their caliber at close range (100 m). At longer ranges (500-1,000 m), this dropped to 1.5-1.1 calibers due to the poor ballistic shape and higher drag of the smaller-diameter early projectiles. Later in the conflict, APCBC fired at close range (100 m) from large-caliber, high-velocity guns (75–128 mm) were able to penetrate a much greater thickness of armor in relation to their caliber (2.5 times) and also a greater thickness (2-1.75 times) at longer ranges (1,500-2,000 m). Comparative testing of British [[Ordnance QF 17 pounder]] APCBC rounds fired into captured German [[Panther tank]]s indicated the APCBC munitions were more accurate than late war [[armour-piercing discarding sabot]] (APDS) shot.<ref>U.S. Army Firing Test No.3, U.S. Army Firing Tests conducted August 1944 by 12th U.S. Army Group at Isigny, France. Report of tests conducted during 20–21 August 1944.</ref> |
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APCBC shot was produced for a wide range of anti-tank artillery ranging from 2 pounders to the German 88 mm. This type of munition was also designated as APBC (Armor Piercing Ballistic Capped), in reference to the Soviet version of APCBC. APCBC shot was also used in naval armaments in WWII. After World War II, the trend in armor piercing munitions development centered on sub-caliber projectiles. No tank guns designed since the late 1950s have used full-caliber AP, APC, or APCBC ammunition.<ref>Orgokiewicz, p. 77.</ref> |
APCBC shot was produced for a wide range of anti-tank artillery ranging from 2 pounders to the German 88 mm. This type of munition was also designated as APBC (Armor Piercing Ballistic Capped), in reference to the Soviet version of APCBC. APCBC shot was also used in naval armaments in WWII. After World War II, the trend in armor piercing munitions development centered on sub-caliber projectiles. No tank guns designed since the late 1950s have used full-caliber AP, APC, or APCBC ammunition.<ref>Orgokiewicz, p. 77.</ref> |
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Latest revision as of 19:27, 9 May 2020
.jpg){kind=link}
Unexploded British naval 15-inch shell in Genoa Cathedral, fired in 1941, with its armor-piercing cap on the floor to the left. The ballistic cap is absent.
The armour-piercing capped ballistic cap (APCBC) is a type of armor-piercing shell introduced in the 1930s.
Development
The APCBC munition type was an evolutionary development of the early war armour-piercing capped (APC) shell, itself an evolution of the more basic AP (armor piercing or solid shot) and APHE (armor piercing high explosive) shell types. With respect to armored land warfare, the primary intended function of both AP and APHE shell types was to penetrate an enemy armored vehicle and incapacitate the vehicle and crew by internal explosion (in the case of APHE) or fragmentation/ricochet (in the case of AP rounds). As the war lengthened, target armor became progressively thicker (and sloped) as new tank designs emerged, and early war AP and APHE became progressively less effective. The initial response to this thickening in armor had been to increase the muzzle velocity in newly developed anti-tanks guns. However, it was found that steel shot tended to shatter on impact at velocities upward of about 823 m/s (2700 feet/second).[1][2]
Based on this deficiency, a new form of shell was developed which was designated APC (armor piercing capped). In this form of munition, a cap of softer metal was attached to the tip of an AP (solid) round. The purpose of this cap was manifold. The cap transferred energy from the tip of the shell to the sides of the projectile, thereby helping to reduce shattering. In addition, the cap appeared to improve penetration of sloped armor by deforming, spreading and “sticking” to the armor on impact and thereby reducing the tendency of the shell to deflect at an angle. However, the cap structure of the APC shell reduced the aerodynamic efficiency of the round with a resultant reduction in accuracy and range'[1][2]
To address the reduction in accuracy caused by the addition of a cap to an AP round, a second cap or cover was introduced in the design of APCBC munition. This involved fitting a streamlined ballistic cap over the APC, thereby increasing accuracy, reducing in-flight loss of velocity and increasing penetration.[3] Early WWII-era uncapped AP projectiles fired from high-velocity guns were able to penetrate about twice their caliber at close range (100 m). At longer ranges (500-1,000 m), this dropped to 1.5-1.1 calibers due to the poor ballistic shape and higher drag of the smaller-diameter early projectiles. Later in the conflict, APCBC fired at close range (100 m) from large-caliber, high-velocity guns (75–128 mm) were able to penetrate a much greater thickness of armor in relation to their caliber (2.5 times) and also a greater thickness (2-1.75 times) at longer ranges (1,500-2,000 m). Comparative testing of British Ordnance QF 17 pounder APCBC rounds fired into captured German Panther tanks indicated the APCBC munitions were more accurate than late war armour-piercing discarding sabot (APDS) shot.[4] APCBC shot was produced for a wide range of anti-tank artillery ranging from 2 pounders to the German 88 mm. This type of munition was also designated as APBC (Armor Piercing Ballistic Capped), in reference to the Soviet version of APCBC. APCBC shot was also used in naval armaments in WWII. After World War II, the trend in armor piercing munitions development centered on sub-caliber projectiles. No tank guns designed since the late 1950s have used full-caliber AP, APC, or APCBC ammunition.[5]
Notes
- ↑ 1.0 1.1 "Hobby". Flamesofwar.com. http://www.flamesofwar.com/hobby.aspx?art_id=836. Retrieved 2010-06-12.
- ↑ 2.0 2.1 "Juno Beach Centre - Anti-Tank Projectiles". Junobeach.org. http://www.junobeach.org/e/4/can-tac-art-atp-e.htm. Retrieved 2010-06-12.
- ↑ "Anti-Tank". Members.tripod.com. 1943-03-06. http://members.tripod.com/~nigelef/anti-tank.htm. Retrieved 2010-06-12.
- ↑ U.S. Army Firing Test No.3, U.S. Army Firing Tests conducted August 1944 by 12th U.S. Army Group at Isigny, France. Report of tests conducted during 20–21 August 1944.
- ↑ Orgokiewicz, p. 77.
References
- Orgokiewicz, Richard M. Technology of Tanks, Volume I. Coulsdon: Jane's Information Group, 1991.
- http://web.archive.org/web/20090812141445/http://www.wargaming.info/ww2/ustest3.htm
- British Anti-tank Artillery 1939-45. C. Henry, B. Delf. Edition: illustrated. Osprey Publishing, 2004
The original article can be found at APCBC and the edit history here.