Spike Missile

Tungsten alloy rod has the advantage of high density,excellent hardness,superior high tensile strength.etc. Tungsten alloy rod can be used as warhead of Spike Missile.

Spike is a fourth generation man-portable fire-and-forget anti-tank guided missile and anti-personnel missile with a tandem-charged HEAT warhead, developed and designed by the Israeli company Rafael Advanced Defense Systems and in service with a number of nations.

As well as engaging and destroying targets within the line-of-sight of the launcher ("fire-and-forget"), some variants of the missile are capable of making a top-attack profile through a "fire, observe and update" guidance method; the operator tracking the target, or switching to another target, optically through the trailing fiber-optic wire while the missile is climbing to altitude after launch. This is similar to the lofted trajectory flight profile of the US FGM-148 Javelin.

Spike is a fire-and-forget missile with lock-on before launch and automatic self-guidance. The missile is equipped with an imaging infrared seeker.

The medium, long and extended range versions of the Spike also have the capability of "Fire, Observe and Update" operating mode. The missile is connected by a fiber-optical wire that is spooled out between the launch position and the missile. With this the operator can obtain a target if it is not in the line of sight of the operator at launch, switch targets in flight, or compensate for the movement of the target if the missile is not tracking the target for some reason. Hence, the missile can be fired speculatively for a target of opportunity, or to provide observation on the other side of an obstacle. The missile has a soft launch capability – the motor firing after the missile has left the launcher- which allows for the missile to be fired from confined spaces, which is a necessity in urban warfare.

The missile uses a tandem warhead – two shaped charges, a precursor warhead to detonate any explosive reactive armor and a primary warhead to penetrate the underlying armor. Currently, it is replacing aging second generation anti-tank missiles like the MILAN and M47 Dragon in the armies of the user nations.

FIM-92 Stinger

Tungsten alloy rod has so many advantages, such as high density, high melting point, small volume, excellent hardness, superior wearing resistance, high ultimate tensile strength, high ductility, high temperature resistance, etc. The warhead of FIM-92 Stinger is made of tungsten alloy rod.

The FIM-92 Stinger is a personal portable infrared homing surface-to-air missile (SAM), which can be adapted to fire from ground vehicles or helicopters (as an AAM), developed in the United States and entered into service in 1981. Used by the militaries of the United States and by 29 other countries, it is manufactured by Raytheon Missile Systems and under license by EADS in Germany, with 70,000 missiles produced. It is classified as a Man-Portable Air-Defense System (MANPADS).

Light to carry and easy to operate, the FIM-92 Stinger is a passive surface-to-air missile, shoulder-fired by a single operator, although officially it requires two. The FIM-92B missile can also be fired from the M-1097 Avenger and M6 Linebacker. The missile is also capable of being deployed from a Humvee Stinger rack, and can be used by paratroopers. A helicopter launched version exists called Air-to-Air Stinger (ATAS).

Tungsten Alloy Ball & JDAM

Tungsten alloy ball is small in volume but very dense, which means the product can be used in various fields requiring small but heavy parts.
Tungsten alloy ball can be used for warhead of JDAM.

The Joint Direct Attack Munition (JDAM) is a guidance kit that converts unguided bombs, or "dumb bombs" into all-weather "smart" munitions. JDAM-equipped bombs are guided by an integrated inertial guidance system coupled to a Global Positioning System (GPS) receiver, giving them a published range of up to 15 nautical miles (28 km). JDAM-equipped bombs range from 500 pounds (227 kg) to 2,000 pounds (907 kg). When installed on a bomb, the JDAM kit is given a GBU (Guided Bomb Unit) nomenclature, superseding the Mark 80 or BLU (Bomb, Live Unit) nomenclature of the bomb to which it is attached.

The JDAM is not a stand-alone weapon, rather it is a "bolt-on" guidance package that converts unguided gravity bombs into Precision-Guided Munitions, or PGMs. The key components of the system consist of a tail section with aerodynamic control surfaces, a (body) strake kit, and a combined inertial guidance system and GPS guidance control unit.

The JDAM was meant to improve upon laser-guided bomb and imaging infrared technology, which can be hindered by bad ground and weather conditions. Laser seekers are now being fitted to some JDAMs.

From 1998 to 20 August 2013, Boeing delivered 250,000 JDAM kits, producing over 40 guidance kits per day.

Tungsten Alloy Military Swaging Rod FOR AIM-120 AMRAAM

Swaging greatly increases tungsten alloy rod's ultimate tensile strength. The ultimate tensile strength of regular tungsten alloy rod is 1050 MPa . However, after swaging, the ultimate tensile strength can reach 1200 MPa min, we can even control tungsten alloy military swaging rod at 1400 MPa. Tungsten alloy military swaging rod is one of our main products. The composition of tungsten alloy military swaging rod is 93%WNiFe.

The warhead of AIM-120 AMRAAM is made by tungsten alloy military swaging rod.

The AIM-120 Advanced Medium-Range Air-to-Air Missile, or AMRAAM (pronounced "am-ram"), is a modern beyond-visual-range air-to-air missile (BVRAAM) capable of all-weather day-and-night operations. Designed with the same form-and-fit factors as the previous generation of semiactive guided Sparrow missiles, it is a fire-and-forget missile with active guidance. When an AMRAAM missile is being launched, NATO pilots use the brevity code - Fox Three.AMRAAM was developed as the result of an agreement (the Family of Weapons MOA, no longer in effect by 1990), among the United States and several other NATO nations to develop air-to-air missiles and to share production technology. Under this agreement the U.S. was to develop the next generation medium range missile (AMRAAM) and Europe would develop the next generation short range missile (ASRAAM). When the German ASRAAM seeker development ran into problems, the MOA was abrogated and this breakdown led to the U.S. developing AIM-9X Sidewinder and Germany the IRIS-T.[citation needed] Although Europe initially adopted the AMRAAM, an effort to develop the MBDA Meteor, a competitor to AMRAAM, was begun in Great Britain. Eventually the ASRAAM was developed solely by the British, but using another source for its infrared seeker. After protracted development, the deployment of AMRAAM (AIM-120A) began in September 1991 in U.S. Air Force F-15 Eagle fighter squadrons. The U.S. Navy soon followed (in 1993) in its the F/A-18 Hornet squadrons.

The eastern counterpart of AMRAAM is the somewhat similar Russian Air Force AA-12 "Adder", sometimes called in the West as the "AMRAAMski." Likewise, France began its own air-to-air missile development with the MICA concept that used a common airframe for separate radar-guided and infrared-guided versions.

Tungsten Alloy Gyroscoper Rotor For F/A-18E/F Super Hornet

A tungsten alloy gyroscope rotor is a device for measuring or maintaining orientation, based on the principles of angular momentum. A mechanical they are essentially a spinning wheel or disk whose axle is free to take any orientation. This orientation changes much less in response to a given external torque than it would without the large angular momentum associated with the gyroscope's high rate of spin. Since external torque is minimized by mounting the device in gimbals, its orientation remains nearly fixed, regardless of any motion of the platform on which it is mounted. Solid state gyroscopes also exist.

F/A-18E/F Super Hornet adopts tungsten alloy gyroscope.

The Boeing F/A-18E/F Super Hornet is a twin-engine carrier-based multirole fighter aircraft variant based on the McDonnell Douglas F/A-18 Hornet. The F/A-18E single-seat and F/A-18F tandem-seat variants are larger and more advanced derivatives of the F/A-18C and D Hornet. The Super Hornet has an internal 20 mm gun and can carry air-to-air missiles and air-to-surface weapons. Additional fuel can be carried in up to five external fuel tanks and the aircraft can be configured as an airborne tanker by adding an external air refueling system.

Designed and initially produced by McDonnell Douglas, the Super Hornet first flew in 1995. Full-rate production began in September 1997, after the merger of McDonnell Douglas and Boeing the previous month. The Super Hornet entered service with the United States Navy in 1999, replacing the Grumman F-14 Tomcat, which was retired in 2006, and serves alongside the original Hornet. The Royal Australian Air Force (RAAF), which has operated the F/A-18A as its main fighter since 1984, ordered the F/A-18F in 2007 to replace its aging F-111 fleet. RAAF Super Hornets entered service in December 2010.

Tungsten Alloy Armor Piercing Bullet for Barret M82

Tungsten alloy armor piercing bullet relying on the kinetic energy of the projectile, penetrates armor and destroys the target. Its characteristic is high velocity, long hitting the distance and good accuracy.It used for mutilate tanks, self-propelled guns, armored vehicles, ships, aircraft, or any other armored target.

Tungsten alloy armor piercing bullet is a type of ammunition designed to penetrate armor and detonate. They are generally used against body armor, vehicle armor, tanks and other defenses, depending on the caliber of the firearms.Tungsten alloy armor piercing bullet is adopted by Barret M82.

The M82 is a recoil-operated, semi-automatic anti-materiel rifle developed by the American Barrett Firearms Manufacturing company. A heavy SASR (Special Application Scoped Rifle), it is used by many units and armies around the world. It is also called the "Light Fifty" for its .50 BMG (12.7×99mm NATO) chambering. The weapon is found in two variants, the original M82A1 (and A3) and the bullpup M82A2. The M82A2 is no longer manufactured, though the XM500 can be seen as its successor.

APFSDS for K2

Tungsten alloy armor piercing fin stabilized discarding sabot (APFSDS) is a type of ammunition which, like a bullet, does not contain explosives and uses kinetic energy to penetrate the target. The term can apply to any type of armor-piercing shot but typically refers to a modern type of armor piercing weapon, the tungsten alloy armo piercing fin stabilized discarding sabot, a type of long-rod penetrator (LRP), and not to small arms bullets. K2 adopts tungsten alloy armor piercing fin stabilized discarding sabot

K2 Black Panther (Hangul: K2 '흑표'; Hanja: K2 '黒豹') is a South Korean main battle tank that will replace most of the various models of M48 Patton tanks and complement the K1 series of main battle tanks currently fielded by the Republic of Korea. K2 are not mass-produced due to serious troubles of transmission and main engine. However, The K2 Black Panther is the second most expensive tank in the world behind only the AMX-56 in price cost. A single K2 unit costs over US$8.5 million per unit.

In March, 2011, South Korea's Defense Acquisition Program Administration (DAPA) announced that mass production of the K2, which the Army was expecting to deploy in 2012, will not happen until 2013 due to problems concerning its engine and transmission. In April 2012 DAPA announced that due to ongoing issues with the reliability and durability of the domestically-produced powerpack, the first 100 production K2s would use a German engine and transmission and that service entry would be delayed until March 2014.

Main armament: L55 120 mm smoothbore gun, Rheinmetall licensee (developed under license by the Agency for Defense Development and manufactured by World Industries Ace Corporation). This is complemented by an autoloader, similar to that designed for Leclerc, it can fire about 15 - 20 rounds a minute or every 3 – 4 seconds and reloads about every 1 – 2 seconds, without being affected by the gun's angle. The ammunition for the main gun is loaded in a 16-shell magazine, with a total ammunition capacity of 40.

Secondary Weapons: 12.7 mm K-6 heavy machine gun; 7.62 mm coaxial machine gun.

Tungsten Alloy Swaging Rod for DF-21

Tungsten alloy swaging rod is made of tungsten alloy rod through calcinations. The normal method used in the processing are extruding, forging and sintering. After calcinations, tungsten alloy swaging rod has higher ductility, toughness and tensile strength than tungsten alloy rod, so it can be used for a longer time. Tungsten alloy swaging rod is widely used in industry as well as military areas, such as rifle bullet, armor piercing, snipe rifle penetrator, etc.

Advantages of tungsten alloy swaging rod: low cost, easy operation, convenient processing adjustment and control, harder, more durable, excellent hardness (40HRC, tungsten alloy rod between 26HRC and 30HRC), high ultimate tensile strength (1200MPa~1400MPa), etc.

Tunsgten alloy swaging rod can be used for DF-21 which can anti flying carrier.

The Dong-Feng 21 (DF-21; NATO reporting name CSS-5 - Dong-Feng (Chinese: 東風; literally "East Wind") is a two-stage, solid-propellant, single-warhead medium-range ballistic missile (MRBM) in the Dong Feng series developed by China Changfeng Mechanics and Electronics Technology Academy. Development started in the late 1960s and was completed around 1985-86, but it was not deployed until 1991. It was developed from the submarine-launched JL-1 missile, and is China's first solid-fuel land-based missile. The U.S. Department of Defense in 2008 estimated that China had 60-80 missiles and 60 launchers.

Originally developed as a strategic weapon, the DF-21's later variants were designed for both nuclear and conventional missions. As well as a nuclear warhead of around 300 kt, it is thought that high explosive, submunition and chemical warheads are available. The latest DF-21D was said to be the world's first anti-ship ballistic missile (ASBM). The DF-21 has also been developed into a space-capable anti-satellite/anti-missile weapon carrier.

Tungsten Alloy Swaging Rod for Kinetic Energy Penetrator

Swaging greatly increases tungsten alloy rod's ultimate tensile strength. The ultimate tensile strength of regular tungsten alloy rod is 1050 MPa . However, after swaging, the ultimate tensile strength can reach 1200 MPa min, we can even control tungsten alloy military swaging rod at 1400 MPa. Tungsten alloy military swaging rod is one of our main products. The composition of tungsten alloy military swaging rod is 93%WNiFe. Tungsten alloy military swaging rod can be used for tungsten kinetic energy penetrator.

Tungsten kinetic energy penetrator is a kind of penetrator used by Leopard 2E

The Leopard 2E or Leopard 2A6E (E stands for España, Spanish for Spain) is a variant of the German Leopard 2 main battle tank, tailored to the requirements of the Spanish army, which acquired it as part of an armament modernization program named Programa Coraza, or Program Breastplate. The acquisition program for the Leopard 2E began in 1994, five years after the cancellation of the Lince tank program that culminated in an agreement to transfer 108 Leopard 2A4s to the Spanish army in 1998 and started the local production of the Leopard 2E in December 2003. Despite postponement of production owing to the 2003 merger between Santa Bárbara Sistemas and General Dynamics, and continued fabrication issues between 2006 and 2007, 219 Leopard 2Es have been delivered to the Spanish army.

The Leopard 2E is a major improvement over the M60 Patton tank, which it replaced in Spain's mechanized and armored units. Its development represented a total of 2.6 million man-hours worth of work, 9,600 of them in Germany, at a total cost of 2.4 billion euros. This makes it one of the most expensive Leopard 2s built. Indigenous production amounted to 60% and the vehicles were assembled locally at Sevilla by Santa Bárbara Sistemas. It has thicker armor on the turret and glacis plate than the German Leopard 2A6, and uses a Spanish-designed tank command and control system, similar to the one fitted in German Leopard 2s. The Leopard 2E is expected to remain in service until 2025.

Tungsten Alloy Swaging Rod for MIM-104 Patriot

Tungsten alloy swaging rod is made of tungsten alloy rod through calcinations. The normal method used in the processing are extruding, forging and sintering. After calcinations, tungsten alloy swaging rod has higher ductility, toughness and tensile strength than tungsten alloy rod, so it can be used for a longer time. Tungsten alloy swaging rod is widely used in industry as well as military areas, such as rifle bullet, armor piercing, snipe rifle penetrator, etc.

Tungsten alloy swaging rod can be used for MIM-104 Patriot. MIM Patriot utilizes kinetic energy to destroy missiles and aircraft.

The MIM-104 Patriot is a surface-to-air missile (SAM) system, the primary of its kind used by the United States Army and several allied nations. It is manufactured by the Raytheon Company of the United States, and derives its name from the Radar component of the weapon system. The AN/MPQ-53 at the heart of the system is known as the "Phased Array Tracking Radar to Intercept On Target" or the bacronym PATRIOT. The Patriot System replaced the Nike Hercules system as the U.S. Army's primary High to Medium Air Defense (HIMAD) system, and replaced the MIM-23 Hawk system as the U.S. Army's medium tactical air defense system. In addition to these roles, Patriot has been given the function of the U.S. Army's anti-ballistic missile (ABM) system, which is now Patriot's primary mission.

Patriot uses an advanced aerial interceptor missile and high performance radar systems. Patriot was developed at Redstone Arsenal in Huntsville, Alabama, which had previously developed the Safeguard ABM system and its component Spartan and Sprint missiles. The symbol for Patriot is a drawing of a Revolutionary War-era Minuteman.

Patriot systems have been sold to Taiwan, Egypt, Germany, Greece, Israel, Japan, Kuwait, the Netherlands, Saudi Arabia, United Arab Emirates, Jordan and Spain. Poland hosts training rotations of a battery of U.S. Patriot launchers. It was first deployed in Morąg in 24 May 2010 but has since been moved to Toruń and Ustka. South Korea also purchased several second-hand Patriot systems from Germany after North Korea test-launched ballistic missiles to the Sea of Japan and proceeded with underground nuclear testing in 2006. On 4 December 2012, NATO authorized the deployment of Patriot missile launchers in Turkey to protect the country from missiles fired in the civil war in neighboring Syria.

Tungsten Alloy Ball for Cluster Munition

Tungsten alloy ball is small in volume but very dense, which means the product can be used in various fields requiring small but heavy parts, such as the counterweights for golf club, fishing weights, counterweights for military applications, projectiles in the missile weapons, armor piercing ammunition, hunting pellets, prefabricated fragments, the missile weapons, armor piercing ammunition; counterweights for oil logging; also some fields concerning with precision industry, such as mobile phone vibrator, clock cube, self-winding watches, anti-vibration toll holders, flywheel weights, etc. Heavy tungsten alloy balls or tungsten weight is widely used in weight or balance industrial, and in military.

A cluster munition is a form of air-dropped or ground-launched explosive weapon that releases or ejects smaller submunitions. Commonly, this is a cluster bomb that ejects explosive bomblets that are designed to kill personnel and destroy vehicles. Other cluster munitions are designed to destroy runways or electric power transmission lines, disperse chemical or biological weapons, or to scatter land mines. Some submunition-based weapons can disperse non-munitions, such as leaflets.

Because cluster bombs release many small bomblets over a wide area they pose risks to civilians both during attacks and afterwards. During attacks, the weapons are prone to indiscriminate effects, especially in populated areas. Unexploded bomblets can kill or maim civilians and/or unintended targets long after a conflict has ended, and are costly to locate and remove.

Modern cluster bombs and submunition dispensers are often multiple-purpose weapons, containing mixtures of anti-armor, anti-personnel, and anti-materiel munitions. The submunitions themselves may also be multi-purpose, such as combining a shaped charge, to attack armour, with a fragmenting case, to attack infantry, material, and light vehicles. Modern multipurpose munitions may also have an incendiary effect.

Tungsten Alloy Hand Grenade

With the development of economic and military industry, tungsten heavy alloy is increasingly adopted as the raw material for military defense products in recent years, because people find tungsten alloy has so many good advantages in military areas: high density, high melting point, high corrosion resistance and low vapor pressure, so nowadays military weapons is widely uses tungsten alloy as materials: tungsten alloy hand grenade, tungsten alloy bullet, tungsten alloy armor and shells, tungsten alloy rockets components, etc.

Hand grenade is made up of three parts: filler, body and fuze assembly.
Filler: the filler is composed of a chemical or explosive substance, which determines the type of it for employment factors. All fillers in they are mixed with silica aerogel for increased dissemination efficiency.
Body: the body of tungsten alloy grenade contains filler and fragmentation. The body of hand grenade contains a primer, first fire mixture, pyrotechnic delay column, and ignition mixture. Assembled to the body are a striker, striker spring, safety lever, and safety pin with pull ring. The split end of the safety pin has an angular spread.
Fuze assembly: fuze assembly in hand grenade causes the hand grenade to ignite or explode by detonating the filler.

Speciation of Tungsten Alloy Hand Grenade:

Diameter: 53mm
Length: 104 mm
Weight: 130g
Throwing Distance: 30 ~ 50 m
Exclusive Feature: hand grenade is the safe and environmentally friendly weapon so that it is widely used in army.

Tungsten Alloy Rod for Anti-satellite Weapon

Tungsten alloy rod has so many advantages, such as high density, high melting point, small volume, excellent hardness, superior wearing resistance, high ultimate tensile strength, high ductility, high temperature resistance, etc. Tungsten alloys can be widely produced into it used in many industry sectors.Tungsten alloy rod can be used for Anti-satellite weapon.

The development and design of anti-satellite weapons has followed a number of paths. The initial efforts by the USA and the USSR were using ground-launched missiles from the 1950s; many more exotic proposals came afterwards.

In the late 1950s the U.S. Air Force started a series of advanced strategic missile projects under the designation Weapon System WS-199A. One of the projects studied under the 199A umbrella was Martin's Bold Orion air-launched ballistic missile (ALBM) for the B-47 Stratojet, based on the rocket motor from the Sergeant missile. Twelve test launches were carried out between 26 May 1958 and 13 October 1959, but these were generally unsuccessful and further work as an ALBM ended. The system was then modified with the addition of an Altair upper stage to create an anti-satellite weapon with a 1100-mile (1700-km) range. Only one test flight of the anti-satellite mission was carried out, making a mock attack on the Explorer 6 at an altitude of 156 miles (251 km). To record its flight path, the Bold Orion transmitted telemetry to the ground, ejected flares to aid visual tracking, and was continuously tracked by radar. The missile successfully passed within 4 miles (6.4 km) of the satellite, which would be suitable for use with a nuclear weapon, but useless for conventional warheads.[1]

A similar project carried out under 199A, Lockheed's High Virgo, was initially another ALBM for the B-58 Hustler, likewise based on the Sergeant. It too was adapted for the anti-satellite role, and made an attempted intercept on Explorer 5 on 22 September 1959. However, shortly after launch communications with the missile were lost and the camera packs could not be recovered to see if the test was successful. In any event, work on the WS-199 projects ended with the start of the AGM-48 Skybolt project. Simultaneous U.S. Navy projects were also abandoned although smaller projects did continue until the early 1970s.

The use of high altitude nuclear explosions to destroy satellites was considered after the tests of the first conventional missile systems in the 1960s. During the Hardtack Teak test in 1958 observers noted the damaging effects of the electromagnetic pulse (EMP) caused by the explosions on electronic equipment, and during the Starfish Prime test in 1962 the EMP from a 1.4 Mt warhead detonated over the Pacific damaged three satellites and also disrupted power transmission and communications across the Pacific. Further testing of weapons effects was carried out under the DOMINIC I series. An adapted version of the nuclear armed Nike Zeus was used for an ASAT from 1962. Codenamed Mudflap, the missile was designated DM-15S and a single missile was deployed at the Kwajalein atoll until 1966 when the project was ended in favour of the USAF Thor-based Program 437 ASAT which was operational until 6 March 1975.

Another area of research was directed into energy weapons, including a nuclear-explosion powered X-ray laser proposal developed at Lawrence Livermore National Laboratory (LLNL) in 1968. Other research was based on more conventional lasers or masers and developed to include the idea of a satellite with a fixed laser and a deployable mirror for targeting. LLNL continued to consider more edgy technology but their X-ray laser system development was cancelled in 1977 (although research into X-ray lasers was resurrected during the 1980s as part of the SDI).

ASATs were generally given low priority until 1982, when information about a successful USSR program became widely known in the west. A "crash program" followed, which developed into the Vought ASM-135 ASAT, based on the AGM-69 SRAM with an Altair upper stage. The system was carried on a modified F-15 Eagle that carried the missile directly under the central line of the plane. The F-15's guidance system was modified for the mission and provided new directional cueing through the pilot's heads up display, and allowed for mid-course updates via a data link. The first launch of the new anti-satellite missile took place in January 1984. The first, and only, successful interception was on September 13, 1985. The F-15 took off from Edwards Air Force Base, climbed to 38,100 feet (11,613 m)[2] and vertically launched the missile at the Solwind P78-1, a U.S. gamma ray spectroscopy satellite orbiting at 555 km (345 mi), which was launched in 1979.[3] Although successful, the program was cancelled in 1988.

On February 21, 2008, USA destroyed a malfunctioning U.S. spy satellite USA-193 using a RIM-161 Standard Missile 3.

Tungsten Alloy Radiation Shield for Los Angeles-class Submarine

Tungsten Alloy Radiation Shield is a best choice for radiation shielding applications, which could be used in both medical fields and industrial areas. Compared to traditional radiation shielding materials, such as lead, it provides excellent properties. High-density alloy can provide the same energy absorption as lead using 1/3 less material. People are taking advantage of tungsten alloy's reliable radiation shielding properties. Tungsten alloy radiation shielding can be use for nuclear power plants of  Los Angeles-class Submarine.

The Los Angeles-class, sometimes called the LA-class or the 688-class, is a class of nuclear-powered fast attack submarines that forms the backbone of the U.S. Navy's submarine force, with 62 submarines of this class being completed. As of late 2012, 42 of the class are still in commission and 20 retired from service, mostly due to their mid-life reactor refuelings being cancelled. A further four boats were proposed by the Navy, but later cancelled.

The Los Angeles class contains more nuclear submarines than any other class in the world. The class was preceded by the Sturgeon class and followed by the Seawolf. Except for USS Hyman G. Rickover (SSN-709), all submarines of this class are named after American cities and a few towns (e.g. Key West, Florida and Greeneville, Tennessee). This system of naming broke a long-standing tradition in the U.S. Navy of naming attack submarines for creatures of the ocean (e.g. USS Nautilus (SSN-571)).

The final 23 boats of the Los Angeles class were designed and built to be quieter than their predecessors and also to carry more-advanced sensor and weapons systems. These advanced boats were also designed for operating beneath the polar ice cap. Their diving planes were placed at their bows rather than on their sails, and they have stronger sails for penetrating thick ice.

According to the U.S. Department of Defense, the top speed of the submarines of the Los Angeles class is over 25 knots (29 mph or 46 kph), although the actual maximum is classified. Some published estimates have placed their top speed at 30 to 33 knots. In his book Submarine: A Guided Tour Inside a Nuclear Warship, Tom Clancy estimated the top speed of Los Angeles-class submarines at about 37 knots.

The U.S. Navy gives the maximum operating depth of the Los Angeles class as 650 feet (200 m), while Patrick Tyler, in his book Running Critical, suggests a maximum operating depth of 950 feet (290 m).Although Tyler cites the 688-class design committee for this figure,the government has not commented on it. The maximum diving depth is 1,475 feet (450 m) according to Jane's Fighting Ships, 2004–2005 Edition, edited by Commodore Stephen Saunders of the Royal Navy.

Los Angeles class submarines carry about 25 torpedo-tube-launched weapons and all boats of the class are capable of launching Tomahawk cruise missiles horizontally (from the torpedo tubes). The last 31 boats of this class also have 12 dedicated vertical launching system (VLS) tubes for launching Tomahawks.

Tungsten Alloy Ball for Phalanx CIWS

Tungsten alloy ball is small in volume but very dense. It is used as ammunition for Phalanx CIWS.

The Phalanx CIWS is a close-in weapon system for defending against anti-ship missiles. It was designed and manufactured by the General Dynamics Corporation, Pomona Division (now a part of Raytheon). Consisting of a radar-guided 20 mm (0.79 in) Gatling gun mounted on a swiveling base, the Phalanx is used by multiple Navies around the world, namely the Royal Navy and the United States Navy on every class of surface combat ship, by the United States Coast Guard aboard its Hamilton-class and Legend-class cutters and the navies of 16 allied nations.

A land based variant known as C-RAM has recently been deployed in a short range missile defense role, to counter incoming rockets and artillery fire.

Because of their distinctive barrel-shaped radome and their automated nature of operation, Phalanx CIWS units are sometimes nicknamed "R2-D2" after the famous droid from Star Wars, and in the Royal Navy as Daleks, after the aliens from Doctor Who.

The basis of the system is the 20 mm M61 Vulcan Gatling gun autocannon, used since the 1960s by the United States military in nearly all fighter aircraft (and one land mounting, the M163 VADS), linked to a Ku-band radar system for acquiring and tracking targets. This proven system was combined with a purpose-made mounting, capable of fast elevation and traverse speeds, to track incoming targets. An entirely self-contained unit, the mounting houses the gun, an automated fire control system and all other major components, enabling it to automatically search for, detect, track, engage and confirm kills using its computer-controlled radar system. Due to this self-contained nature, Phalanx is ideal for support ships which lack integrated targeting systems and generally have limited sensors. The entire unit has a mass between 5,500 and 6,100 kg (12,400 to 13,500 lb).

Due to the continuing evolution of both threats and computer technology, the Phalanx system has, like most military systems, been developed through a number of different configurations. The basic (original) style is the Block 0, equipped with first generation solid state electronics and with marginal capability against surface targets. The Block 1 (1988) upgrade offered various improvements in radar, ammunition, rate of fire, increasing engagement elevation to +70 degrees, and computing. These improvements were intended to increase the system's capability against emerging Russian supersonic anti-ship missiles. Block 1A introduced a new computer system to counter more maneuverable targets. The Block 1B PSuM (Phalanx Surface Mode, 1999) adds a forward looking infrared (FLIR) sensor to allow the weapon to be used against surface targets.[9] This addition was developed to provide ship defense against small vessel threats and other "floaters" in littoral waters and to improve the weapon's performance against slower low-flying aircraft. The FLIR's capability is also of use against low-observability missiles and can be linked with the RIM-116 Rolling Airframe Missile (RAM) system to increase RAM engagement range and accuracy. The Block 1B also allows for an operator to visually identify and target threats.

The U.S. is in the process of upgrading all their Phalanx systems to the Block 1B configuration. The Block 1B is also used by other navies such as Canada, Portugal, Japan, Egypt, Bahrain and the UK.

In May 2009, the US Navy awarded a $260 million contract to Raytheon Missile Systems to perform upgrades and other work on the Phalanx. The work is to be completed by September 2012.

Theory of Tungsten Alloy Armor Piercing Bullets

Tungsten alloy armor piercing bullets are famous for their ability to penetrate target. It is mostly because large kinetic energy and their high tensile strength focused on the target. The bullets are made from the high-density tungsten alloy that is much harder than most armor. All have very hard warheads.

Tungsten alloy armor piercing bullets can be used against tanks, armored vehicles and concrete fortifications. When fired, bullets are under the high-temperature, high-pressure gas. Reach the target; it will make a pit in the surface of the armor, red out the armor and the pit bottom at the same time. At this time, although the head has been broken, missile force the powerful impact of inertia, it will continue onrush. When the impact force reaches a certain value, the fuse is triggered; it caused the explosion of the projectile charge. At this time, exploding charge will create tons of pressure per square centimeter in area, killing the crew inside the tank or destroying armored weapons.

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Tungsten Alloy Cube for Military

Tungsten alloy cube

Density: 16.5-18.75 g/cm3
Composition: W content: 85-99%, W-Ni-Fe, W-Ni-Cu
Supply state: Sinter state, Grind state
Application: balance weight, Military industry.
Advantage: High-density, High absorption capacity against X-rays and gamma rays, Good modulus of elasticity, High hardness.

Consist of 85-98% tungsten with balanced commonly nickel and iron or copper. The alloys are made by liquid-phase sintering to give a structure consisting of almost pure tungsten particles in a matrix of the alloy elements. Tungsten Heavy

Alloys, with densities between 16.9 and 18.1 g/cm3, represent the heaviest materials generally available to the engineer. It has excellent radiation resistance, thermal and electric conductivities, corrosion resistance and machinable. We can offer tungsten alloys with tungsten contents ranging from 85 to 98% with a range of physical and mechanical properties as well as non-magnetic W-Ni-Cu.

The Advantages of Tungsten Alloy cube

Why we adopt tungsten alloy cube for parts of extrusion die instead of lead or aluminum or other materials' block? Because tungsten alloy has high melting point more than ten times higher than lead, which is important in extrusion die process. Then, tungsten alloy has high Mohs hardness. What is the most important reason is that tungsten alloy is environment friendly, which lead can not reach.

Tungsten Alloy Military Properties

Tungsten alloy military properties: high density (60% denser than lead and much denser than steel), high temperature resistance, high melting point, excellent hardness (40HRC, tungsten alloy rod between 26HRC and 30HRC), good corrosion resistance, superior wearing resistance, high ultimate tensile strength (1200MPa~1400MPa), non-toxic and environmentally friendly, etc. Apart form these tungsten alloy properties, tungsten alloy also has military properties. Tungsten military properties: high velocity, long hitting the distance and good accuracy, etc.

As for tungsten alloy properties, it is the best material to make military weapon such as: bullet, armor piercing fin stabilized discarding sabot (APFSDS), flying carrier, armor and shells, shrapnel head, bulletproof vehicles, grenade, tanks panzers, cannons, firearms, etc. The product decide it uses in military field.

Due to the damage to the environment of lead and depleted uranium, tungsten alloy is the first choice and the best alternative to make military weapon for it is denser and harder than other materials. Tungsten alloy has high melting point so it can keep its shape in high temperature. The most important point is that it is non-toxic and environmentally friendly, it can not bring harm to the environment.

Tungsten Alloy Swaging Rod for Armor Piercing

The armor piercing adopted by ZTZ-99 tank is made of tungsten alloy swaging rod. Tungsten alloy swaging rod highly improves the penetration of armor piercing.

Transient high heat loads simulations by using the electron beam facility have been performed on two tungsten heavy alloy swaging rod grades at several power loads with a pulse duration of 5 ms. The cracking patterns of the two tungsten heavy alloy swaging rod grades are quite similar. All cracks occurred along the grain boundary and located across the loaded area. The cracks can be distinguished with two levels, major cracks with larger crack width but lower crack density and microcracks with smaller crack width but higher crack density. The higher the deformation level of tungsten alloy swaging rod for armor piercing and heat loading power density, the smaller the major crack density will be, but there is no obvious difference in the microcracks pattern. No melting occurred for both tungsten alloy swaging rod grades after transient heat loading at power density of 0.88 GW m−2.

Tungsten alloy swaging rod for armor piercing projectile which is made of tungsten alloy comprising a high density penetrator core with a tapered front end and a multi-part outer case in partial contact with the core. This kind of armor piercing projectile will not penetrate because the multi-part jointed case is not as strong as a single-piece, monolithic case. Also, since the hard core is loose and not bonded to the case, then the core can not provide additional structural support. In addition, tungsten alloy swaging rod for armor piercing projectile does not have the ability to either explosively damage the target after penetration, or take data from an instrumentation package during or after penetration.

"Hollow-point" design results in radial expansion of the jacket into "petals" as the tungsten alloy swaging rod travels through the target. Such "flowering" of the case upon impact severely limits the depth of penetration into hardened targets.

Tungsten alloy swaging rod for armor piercing projectile comprising a heavy metal core and a segmented sabot with both right-handed and left-handed threads that separates from the core after exiting the gun's nozzle. It will not penetrate deeply because the nose end is made of a brittle heavy metal alloy, rather than high-strength steel. Also, it requires the use of a discarding sabot carrier.