Wednesday, July 31, 2013

Tungsten Alloy Swaging Rod for Military

Tungsten Alloy Swaging Rod for Military

tungsten alloy swaging rod
Tungsten Alloy Military Swaging Rod

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. Our common types:
Diameter: 12mm~20mm, Length: less than 400mm;
Diameter: 20mm~400mm, Length: less than 500mm.

We can manufacture other products according to customers' specific requirements.

Tungsten Alloy Swaging Rod Main Properties for Military:

* High density 
* High melting point 
* Small volume 
* Excellent hardness 
* Superior wearing resistance 
* High ultimate tensile strength 
* High ductility 
* High temperature resistance 
* Low vapor pressure

Military Application of Tungsten Alloy Swaging Rod

Tungsten alloy swaging rod can be used in military defense, such as depleted uranium kinetic energy penetrators, bullet, armor piercing, armor piercing bullets, sniper rifle penetrator, etc.

Main Processing of Tungsten Alloy Swaging Rod:

1). Mixing
2). Pressing 
3). Sintering 
4). Heat treatment
5). Swaging
6). Machining

Repeated heat treatment and swaging is performed need at least several times.

In this way, tungsten alloy swaging rod can be improved at tensile strength as well decrease elongation and impact toughnes.

Tuesday, July 30, 2013

Tungsten Alloy Swaging Rod Processing

Tungsten Alloy Swaging Rod Processing

tungsten alloy swaging rod
Brief Introduction of Tungsten Alloy Swaging Rod

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.

Tungsten Alloy Swaging Rod Processing:

Firstly, mix tungsten powder together with other elements, such as Ni, Fe, Cu, etc. Put them into a specially designed mold which is in heating furnace. Heat up to a certain temperature and through a certain time, we can get tungsten alloy rod.

Secondly, transfer the rod to a temporary support which supports the tungsten alloy rod is heated three quarters of an hour at about I600°C. In an electrically heated tube furnace, tungsten alloy rod is protected from oxidation at this temperature by hydrogen gas. Tungsten alloy rods are heated to about 1600°C. Then with an atmosphere of hydrogen gas in an electric furnace, tungsten alloy is rapidly passed through the swaging machine. In this operation the diameter of the rod is reduced 10 percent. Tungsten alloy rods are then re-heated in the furnace and are ready for the next pair of swaging dies which will again reduce its diameter by 10 percent.

Thirdly, machining. Tungsten alloy is so hard that it cannot be machined by sharp edge tools, but it can be brought into desire shapes by high temperature hammering or cold grinding.

Monday, July 29, 2013

Tungsten Alloy Military Properties

Tungsten Alloy Military Properties

tungsten alloy military properties
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.

Tungsten Alloy Military Application

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.

We can provide all kinds of tungsten alloy cubes, tungsten alloy balls, tungsten alloy swaging rod and others for military defense in strict according to your requirements. Due to tungsten alloy properties and tungsten alloy good properties, it can be used in many areas.

Sunday, July 28, 2013

Tungsten Alloy Defenses

Tungsten Alloy Defenses

tungsten alloy defense
Tungsten Alloy Defense Technology

Tungsten alloy defense technology in the area of thin-walled guided missiles allows bullets weighing 700 grams to hold 500 grams of effective load. The function of ejection stand off ammunition is to make a barrage out of the tungsten alloy defense, but not to markedly increase their kinetic energy. Nitrified fiber firing ammunition and a high intensity carbon steel ammunition cartridge endows the bullets with 1050metre/sec initial velocity.

Tungsten Military Application in Types of Weapons:

◆The GNU-44 Viper Strike missile, carried by armed drones, has a tungsten sleeve to produce powerful shrapnel.
◆The 130-round-per-second Phalanx anti-missile Gatling gun, deployed on U.S. and Royal Navy ships, originally used DU rounds. They were replaced with tungsten alloy, for environmental reasons.
◆120mm anti-tank rounds use tungsten military application as an alternative to DU in training. So do the 25mm anti-tank rounds, on board the M2/M3 Bradley fighting vehicle.
◆Armor-piercing .308 M993 rifle rounds.
◆The 120mm M1028 anti-personnel round, fired by the Abrams tank. It's basically a giant shotgun shell loaded with 1100 tungsten balls, each 3/8th of an inch big.
◆Dense Inert Metal Explosives, the "focused lethality" ammunition used by the U.S. and Israel. Tungsten military application contains micro-shrapnel made of tungsten powder.
◆Some 70mm rockets fired by Apache helicopters release tungsten military application flechette

We provide assurance to high density of tungsten alloy and military application products use in scientific research and production of national defense industry. We introduced advanced tungsten military application and inspection equipments from domestic and abroad to improve our production capacity, quality of products, and market competition ability. We have two series tungsten alloy defense products with independent intellectual property, high-density tungsten alloy defense and cemented carbide. Our tungsten alloy defense products are widely used in machinery, electronic, mining, building material, oil and national tungsten alloy defense industry. We are striving to provide high quality tungsten alloy defense products and tungsten military application with excellent services and competitive prices. Tungsten alloy defense products and tungsten military application in our company enjoy a good reputation both at home and abroad.

Our high-density tungsten alloy products include tungsten rod (diameter Φ5-Φ300mm, length≤1000mm), tungsten ball (Φ2.0-Φ100mm), tungsten block, tungsten column, electrode, shielding plate, weighing block, fishing sinker, and other special shape products. Density of our high-density tungsten alloy defense products less than 18.7g/cm3. Tungsten alloy defense products and tungsten military application offered by us are qualified.

Thursday, July 25, 2013

Tungsten for Defense

Tungsten for Defense

Advanced Hit Efficiency and Destruction

AHEAD is the acronym of "Advanced Hit Efficiency and Destruction". That AHEAD can also mean "ahead of ….", is indicative of the idea that AHEAD ammunition is a guided missile that is activated and deployed prior to reaching the target, "advancing interception". The core of AHEAD technology is made up of three parts, including AHEAD ammunition, muzzle velocity measurement, and timed detonator device/ data request system.

Below involve the pictures of a typical military application of tungsten alloy in the tungsten military defense (GDF-AHEAD, from Switzerland):

tungsten military defense

Schematic drawing of tungsten military defense( heavy metal tank ammunition cartridge)
tungsten military defense

1. Windshield
2. Tungsten heavy-metal penetrator (sub projectile)
3. Three-section sabot
4. Stabilizing fin
5. Propellant of tungsten military defense

Multi-EFP
Multi-EFP and the combined effect of EFP
(a)Single EFP
(b)The EEP fighting the Department of the composition
(c)Multi-EEP
(d)Integrated effect of EEP

Technological Core of Tungsten Military Defense

The 35mm by 228mm AHEAD ammunition is an original cartridge type, programmed detonator ammunition, composed of a Programmable Fuze System, tungsten alloy subprojectiles, ejection standoff ammunition, a thin-walled body, nitrified fibre firing ammunition and steel ammunition cartridge. This tungsten military defense is become more and more widely used in the military field.

Tungsten Military Defense in Anti-missile:

In the anti-missile role it uses Advanced Hit Efficiency And Destruction (AHEAD) ammunition. This round ejects 152 tungsten projectiles at a predetermined distance, between 40 and 10 m, from the target. A 25-round burst of AHEAD rounds produces 3,800 of these small projectiles to destroy the incoming missile. Cruise missiles can be destroyed at 2.5 km and high speed missiles at 1.5 km range by tungsten military defense. A more common projectile to see in service is the advanced hit efficiency and destruction [AHEAD] round. Given the size of the diameter and the larger length of the projectile, as opposed to a 35mm AHEAD round, more subprojectiles are carried - one hundred and eighty as opposed to one hundred and fifty-two . The submunitions of this tungsten military defense are tungsten-alloy [WHA] spheres, designed for both penetration and 'mass effect', to increase the likelihood of engaging the incoming 'vampire' or 'bogie'. The round is termed the MCP170 and uses a programmable magnetic fuze which uses information provided by the coil velocity gauge near the gun's muzzle in order to automatically compute the correct estimated time to target.

More knowledge of tungsten military defense for AHEAD C141:

The combat efficiency of the AHEAD ammunition is due to the payload of 152 tungsten alloy subprojectiles weighing 3.3 grams each. These subprojectiles are activated at a certain distance in front of the intercepted target, forming a mass of lethal subprojectiles, greatly augmenting the probability of a kill. The tungsten alloy subprojectiles have a sharp edge, ensuring that this tungsten military defense can inroad into the target with precise accuracy, tungsten military defense also provides the kinetic energy to destroy the electrical components, payloads or motor of the target.

Wednesday, July 24, 2013

Tungsten Alloy Military Fittings

Tungsten Alloy Military Fittings

tungsten alloy military fitting
Why Tungsten Heavy Alloy Is Adopted in Military Defense?

Nowadays, tungsten alloy is increasingly adopted as the raw material for military defense, and works as tungsten alloy military fitting, such as bullet, armor and shells, shrapnel head, grenade, bulletproof vehicles, tanks panzers, cannons, firearms, etc. A major tungsten alloy military fitting is in kinetic energy penetrators, where military defenses are in direct competition with depleted uranium (DU). Recent investigations conducted at the Army Research Laboratory show that DU's superior properties resulted from its ability to localize shear during ballistic penetration events. Therefore, military defense was argued that if localized shear can be imparted to tungsten alloy, this material would exhibit penetration performance matching that of depleted uranium (which had become an environmental problem).

You can image the subject envisions a penetrator, dropped from service height of a bomber aircraft, using kinetic energy to penetrate the shielding, and subsequently deliver a nuclear explosive to the buried target.

The problem with such a penetrator is the tremendous heat applied to the penetrator unit when striking the military defense shielding (surface) at hundreds of meters per second. Military defense has partially been solved by using metals such as tungsten (with a much higher melting point than steel), and altering the shape of the projectile (such as an olive). (You can get more information from http://en.wikipedia.org/wiki/Nuclear_bunker_buster)

During the World War Ⅱ, tungsten has already been used as an important raw material for military defense. There were abundant wolfram ore reserves found then in Portugal, which were used to produce tungsten concentrates for military defense.

Tungsten Heavy Alloy for Military Defense and Applications

In order to reduce the adoption of environmental hazardous materials in the military defense field, tungsten alloy military fitting is used as a non-toxic alternative for lead and depleted uranium in bullet and shot. High-density metal such as tungsten alloy military fitting is now widely employed; the goal of military defense is to create functional, high density, non-toxic arms projectiles with controlled impact behavior. The special properties of tungsten alloy make it almost ideal material for military defense applications.

Owing to its great hardness and resistance to high temperature, usage of tungsten alloy military fitting has been steadily increasing since the 1940's.

Tungsten alloy military fitting applications:

*Tungsten alloy bullet
*Shrapnel head
*Balanced ball for missile and plane
*Core for armor-piercing bullet measurement
*Kinetic energy penetrators
*Armor and shells
*Grenade
*Rocket components

Tuesday, July 23, 2013

Tungsten Alloy Counterweight Advantages

Tungsten Alloy Counterweight Advantages

tungsten alloy counterweight
Tungsten alloy counterweight is widely used as counterbalance an opposing mass in a linear or rotary motion system as for its counterweight.

Tungsten alloy is always used for counterbalance an opposing mass in a linear or rotary motion system, allowing movement with lower driving forces.

Tungsten alloy counterweight is designed for aircraft control surfaces, aircraft rotor blades, guidance platforms, and vibration dampening governors. Take vibration dampening governor for instance, tungsten counterweight is used to reduce vibrations in rotating systems such as automobile tires. The vibration is measured without any weights and the heavy spot is determined. It is then placed opposite this heavy spot to balance the load and reduce or eliminate the vibration.

The reasons for adopting tungsten can also be made out of metals such as iron, steel and various alloys. However, tungsten alloy with high density becomes the most popular used material. Take tungsten alloy golf counterweight for instance. When counterweight golf, somebody have the thought of that if they want more distance and control, the conventional wisdom calls for lighter overall weight. But it turned out to be wrong.

Monday, July 22, 2013

Tungsten Ball Pen Bead

Tungsten Ball Pen Bead

tungsten alloy ball
Ballpoint pen or ball-pen is a kind of worldwide popular writing tools in recent decades. It has a simple structure, is easy to carry, provides writing lubrication and it is suitable used as autotype.

Tungsten alloy ball has many advantages, such as high density, small volume, excellent hardness, superior wearing resistance, high ultimate tensile strength, high ductility, high temperature resistance, etc. has a density twice that of steel and are more than 50% heavier than lead, so it is a very suitable material to make into ballpoint bead. These features provide stability when writing, so tungsten alloy ball pen bead will make writing easy and enjoyable. Its wear resistant is the key factor for the manufactures to produce tungsten alloy ball pen bead.

We produce variety of tungsten alloy ball pen bead with diameters of 0.38 - 1.4mm. Our tungsten alloy ball has advanced production techniques and international technical level. Hardness>1400-1500, roughness Ra0.063-0.8 micron, Diameter Tolerance <0.001mm, lineation2000-2500m, wear-out<0.003mm, microspore uniform distribution, writes smoothly, lineation clearing, abrasion proof, long using life , printing ink' wet ability well, carry over more printing ink, lineation clearing ; good handle ,taking bake superabundant printing ink.

All of above superiors make tungsten alloy ball as the best choice for our everyday used pens. Please contact us without hesitation if you have any questions.

Tungsten alloy ball is used in the production of pen bead, tip of ballpoint is generally made of two kinds of material, and one is stainless steel beads and other kind is tungsten alloy ball pen bead. High quality ballpoint tip is made of pure tungsten ball. Ballpoint tip tungsten ball can be used for a long time, and makes writing is also very fluent.
Tungsten alloy ball pen bead is a kind of use the tiny round pearl rotation of the pen, the round pearl by brass, steel or made of tungsten alloy ball, can you write in ink onto the paper will release. Tungsten alloy ball pen bead is different with the reed pen, feather pen, metal tip pen and fountain pen.

How Does Tungsten Alloy Ball Make into Pen Bead?

Tungsten alloy is first made into standard size ball. Then spread out in a groove with the bond and formed into little particles within circular groove, showing tops only. Heavy flat ceiling disk is placed, pressuring little particles from above. In between two dishes into the grinding oil, make these little particles containing diamond powder soaked in gliding mixture. The next step is to turn the footwall, making particles of tungsten alloy ball circular groove constantly tempestuous rolling, in particular of the trench wall, with each other and constant contact, diamond powder keep these particles of the horn side grinding away, they gradually become rounded and light. It takes dozens of hours to finish one tungsten alloy ball pen bead.

Sunday, July 21, 2013

Tungsten Alloy Sphere for Counterweight

Tungsten Alloy Sphere for Counterweight

tungsten alloy sphere
Tungsten alloy sphere counterweights are incorporated into the pitch control system of many propeller designs as a fail-safe device to prevent over speeding. What's more, tungsten heavy alloy is incorporated into the rotating flywheels of gyroscopic controls for the storage of kinetic energy. Tungsten alloy counterweights are used for adjusting the center of gravity of the triangle and the frequency of oscillation of the laser beams. Bucking bars made of tungsten heavy alloy are ideal for vibration-damping applications with high density.

Usually, space for the counterweight is limited, so the need of heavy but small objects is great. Tungsten alloy sphere, with the density of 16.5/ cm 3 to 18.5/m3 about 50 percent higher than lead and much higher than steel, is ideal for counterweight. Tungsten alloy counterweight as sphere can prolong the life of itself because of its wear resistance and round shape. In addition, lead is toxic while tungsten alloy sphere is environmentally friendly.

Tungsten Alloy Sphere Application

Due to its special properties, tungsten alloy sphere use in the counterweight, fishing weight, counterweights, etc. Chinatungsten has more than 20 years of experience in manufacturing tungsten alloy counterweight as sphere. We have tungsten alloy sphere to many different overseas customers and manufactured various parts of tungsten alloy counterweight always meeting specific designs requirement. Tungsten alloy sphere are usually supplied in bulk quantities.

Advantages of Tungsten Alloy Counterweight as Sphere

Tungsten alloy sphere provides a safer alternative to lead, and their higher density enables them to hold their shape better, even under extreme conditions. While uranium offers comparable density, its volatile nature and the special licensing requirements needed for radioactive materials make working with it difficult. Chinatungsten offers a variety of high-density alloys, available as ROTF (Rough, Oversized to Finish) material, bars, tungsten alloy sphere, tungsten alloy counterweight, tungsten alloy plates or rods. We also have extensive machining capabilities, allowing us to provide crankshaft weights in standard sizes or custom products finished to your exact specifications.

Thursday, July 18, 2013

Tungsten Alloy for Shaped Charge Liners

Tungsten Alloy for Shaped Charge Liners

tungsten alloy shaped charge liner
What are Shaped Charge Liners?

A shaped charge liner is an explosive charge shaped to focus the effect of the explosive's energy. Various types are used to cut and form metal, initiate nuclear weapons, and penetrate armor. A typical modern lined shaped charge can penetrate armor steel to a depth of seven or more times the diameter of the charge's cone (cone diameters, CD), though greater depths of 10 CD and above are now feasible.

The shape most commonly used for the liner is a cone, with an internal apex angle of 40 to 90 degrees. Different apex angles yield different distributions of jet mass and velocity. Small apex angles can result in jet bifurcation, or even in the failure of the jet to form at all; this is attributed to the collapse velocity being above a certain threshold, normally slightly higher than the liner material's bulk sound speed. Other widely used shapes include hemispheres, tulips, trumpets, ellipses, and bi-conics; the various shapes yield jets with different velocity and mass distributions.

Liners have been made from many materials, including glass and various metals. The deepest penetrations are achieved with a dense, ductile metal, and a very common choice has been copper. For some modern anti-armor weapons, molybdenum and pseudo-alloys of tungsten filler and copper binder (9:1 thus density is ~18t/m3) have been adopted. Just about every common metallic element has been tried, including aluminum, tungsten, tantalum, depleted uranium, lead, tin, cadmium, cobalt, magnesium, titanium, zinc, zirconium, molybdenum, and beryllium, nickel, silver, and even gold and platinum. The selection of the material depends on the target to be penetrated; for example, aluminum has been found advantageous for concrete targets.

Why Choose Tungsten Alloy as Shaped Charge Liners?

For the deepest penetrations, pure metals yield the best results, because they display the greatest ductility, hence postponing the breakup of the stretching jet into particles. In charges for oil-well completion, however, tungsten alloy shaped charge liner is essential that a solid slug or "carrot" not be formed, since it would plug the hole just penetrated and interfere with the influx of oil. In the petroleum industry, therefore, liners are generally fabricated by powder metallurgy, often of pseudo-alloys, which if tungsten alloy shaped charge liners un-sintered, yield jets that are composed mainly of dispersed fine metal particles.

During World War II, shaped charge liners were made of copper or steel, though other materials were tried or researched. The precision of the charge's construction and shaped charge liners detonation mode were both inferior to modern warheads. This lower precision caused the jet to curve and to break up at an earlier time and hence at a shorter distance. The resulting dispersion decreased the penetration depth for a given cone diameter and also shortened the optimum standoff distance. Since the charges were less effective at larger standoffs, side and turret skirts fitted to some German tanks to protect against Russian anti-tank rifle fire were fortuitously found to give the jet room to disperse and hence reduce its penetrating ability. Now most shaped charge liners are made of tungsten alloy.

The use of shaped charge liners today may increase the penetration of some warheads. Due to constraints in the length of the projectile/missile, the built in stand-off on many warheads is not the optimum distance. The skirting effectively increases the distance between the amour and the target, providing the warhead with a more optimum standoff and greater penetration if the optimum stand-off is not drastically exceeded. Tungsten alloy shaped charge liners should not be confused with cage amour that is used to damage the fusing system of RPG-7 projectiles. The amour works by deforming the inner and outer orgies and shorting the firing circuit between the rocket's piezoelectric nose probe and rear fuse assembly. If the nose probe strikes the amour, the warhead will function as normal.

The spacing between the shaped charge liners and shaped charge liners target is critical, as there is an optimum standoff distance to achieve the deepest penetration. At short standoffs, the jet does not have room to stretch out, and at long standoffs, shaped charge liners eventually breaks into particles, which then tend to drift off the shaped charge liners of axis and to tumble, so that the successive particles tend to widen rather than deepen the hole. At very long standoffs, velocity is lost to air drag, degrading penetration further.

Wednesday, July 17, 2013

Tungsten for Gyroscope Rotors

Tungsten for Gyroscope Rotors

tungsten alloy gyroscope rotor
What Is Tungsten Alloy Gyroscope Rotors?

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.

Applications of Tungsten Alloy Gyroscopes Rotors

Applications of tungsten alloy gyroscopes rotors include navigation (INS) when magnetic compasses do not work (as in the Hubble telescope) or are not precise enough (as in ICBMs) or for the stabilization of flying vehicles like Radio-controlled helicopters or UAVs. Due to higher precision, tungsten alloy gyroscope rotors are also used to maintain direction in tunnel mining.

Gyroscope rotors exhibit a number of behaviors including precession and notations. Tungsten heavy alloy gyroscope rotors can be used to construct gyrocompasses which complement or replace magnetic compasses (in ships, aircraft and spacecraft, vehicles in general), to assist in stability (bicycle, Hubble Space Telescope, ships, vehicles in general) or be used as part of an inertial guidance system. It effects are used in toys like tops, boomerangs, yo-yos, and Powerball's. Many other rotating devices, such as flywheels, behave gyroscopically although the gyroscopic effect is not used.

Tungsten alloy gyroscope rotors in operation have freedom of movement in all three axes. The tungsten alloy gyroscope rotors will maintain its spin axis direction regardless of the orientation of the outer frame. With its perfect properties, tungsten alloy is the perfect material for gyroscope rotors.

Tuesday, July 16, 2013

Tungsten Construction Parts in Gas Lasers

Tungsten Construction Parts in Gas Lasers

tungsten alloy gas lasers
What Is Gas Laser?

A gas laser is a laser in which an electric current is discharged through a gas to produce light. The first gas laser, the Helium-neon, was co-invented by Iranian physicist Ali Javan and American physicist William R. Bennett, Jr. in 1960.Tungsten is the best material to make tungsten alloy gas lasers components. Tungsten alloy gas lasers have so many advantages as follows:

Advantages of Tungsten Alloy Gas Lasers

High volume of active gas lasers material
Active material is relatively inexpensive of gas lasers
Almost impossible to damage the active material in using gas lasers
Heat can be removed quickly from the cavity when using gas lasers
Applications of Tungsten Alloy Gas Laser

Gas laser is mainly used in making holograms.

In laser printing gas laser is used as a source for writing on the photosensitive material.

Gas lasers are used in reading the Bar Code which is imprinted on the product.

Gas lasers related products offered by us are high quality: we can provide gas lasers components as your requirements. Tungsten alloy is a suitable material in making the construction parts in gas lasers. We can provide tungsten alloy products related to gas lasers.

Monday, July 15, 2013

Tungsten Ignition Tubes for Rocket Engine

Tungsten Ignition Tubes for Rocket Engine

tungsten ignition tubes
What is Rocket Engine Ignition Tubes?

A rocket engine tungsten ignition tubes or simply "rocket" is a jet engine that uses only propellant mass for forming its high speed propulsive jet. Rocket engines tungsten ignition tubes are reaction engines and obtain thrust in accordance with Newton's third law. Since tungsten ignition tubes need no external material to form their jet ignition tubes, rocket engines ignition tubes can be used for spacecraft propulsion as well as terrestrial uses, such as missiles. Most rocket engines ignition tubes are internal combustion engines, although non combusting forms also exist.

Rocket engines produce thrust by the expulsion of a high-speed fluid exhaust. Ignition tubes fluid is nearly always a gas which is created by high pressure (10-200 bar) combustion of solid or liquid propellants, consisting of fuel and oxidizer components, within a combustion chamber.

Tungsten Alloy Application for Rocket Engine Ignition Tubes

Because of its superior wear resistance, high melting point, low vapor point and strange hardness, tungsten alloy is increasingly used to manufacture ignition tubes of rocket engines. We can provide ignition tubes for rocket engine as your requirements. Ignition tubes offered by us are qualified.

In rockets, temperatures employed are very often far higher than the melting point of the nozzle and combustion chamber materials. Ignition tubes in rocket engine can overcome this problem; two exceptions are graphite and tungsten (~1200 K for copper). It is important that tungsten ignition tubes be prevented from combusting, melting or vaporizing to the point of failure. Properly manufactured and corrosion shielded tungsten alloy parts will increase safety of any rocket usage.

Sunday, July 14, 2013

Tungsten Alloy for Plasma Technique

Tungsten Alloy for Plasma Technique

tungsten alloy plasma technique
What Is Tungsten Alloy Plasma Technique?

Applications which might gain more importance in the future are construction material for the tungsten alloy plasma technique in magneto hydrodynamic power generation (W and W-Cu) and target plates in fusion reactors (W, W-La2O3).

Recent tungsten alloy plasma technique and theoretical and numerical studies show that tungsten may be the best, if not the only, material to withstand the extraordinary operating conditions in a nuclear fusion reactor diverter. The diverter, being that part of the vacuum vessel where the tungsten alloy plasma technique particles interact with the first wall, and where a large fraction of the fusion heat is removed, consists of water-cooled copper heat-exchanger element covered with a plasma facing armor. The tungsten alloy plasma technique particles (electrons, protons, and α-particles) are directed by the magnetic field toward the diverter target plates, where they are neutralized and pumped. The convective heat flux reaches 20 MW.m-2 and the attendant surface temperature more than 3000℃. Therefore, a suitable armor material must have a high thermal conductivity (in order to transfer high heat fluxes), low thermal expansion coefficient and low Young's modulus (in order to keep thermal stresses low), and a high melting point and low sputtering yield (in order to keep erosion low). Although tungsten does not have as high a thermal conductivity and as low a Young's modulus as carbon-carbon composite materials, which are foreseen for the sections of the diverter with the highest heat flux, many experts believe that, in the long run, reasonable lifetimes will only be achieved by tungsten diverter plates, which have the lowest erosion rates of all materials in sections of the diverter with relatively low plasma temperature but high particle density.

Low-pressure Tungsten Alloy Plasma Technique

For the technical realization of low-pressure plasma processes, one requires equipment with the following components:

Vacuum system (pump, vessel)
Energy supply
Gas supply
Measurement and control components for the reproducible adjustment of the process parameter

Due to the necessity of a vacuum system in most cases, batch operation method is the easiest solution. The processes can be flexibly and complexly configured, in order to change the mode of action of the tungsten alloy plasma technique through variation of the process parameters (pressure, gas flow, gas composition, power) and can attain different effects in one process step. So that, i.e. without great expenditure a secondary cleaning can be carried out and immediately thereafter a corrosion protection layer becomes deposited, without having to aerate in between.

Further Advantages of Low-pressure Tungsten Alloy Plasma Technique:

Ability of fissure-penetration by the plasma: even most complex sample geometries up to porous substrates can be treated
No thermal or mechanical strain of the substrates
High measure on environmental compatibility and operational safety

Chinatungsten Online has diverse facilities available for the various concerted questions (bulk material, batch goods, rail goods, size of the reactor up to 3m 3, MHz- and GHz stimulation); as well as many years of experience in the development of plasma processes and the conception of applicative plasma devices up to pilot graduations.

Within the bounds of its function as service provider in technology transfer, we offer tungsten alloy plasma technique resources for the processing of the above-mentioned industrial questions up to series production. Our service comprises consultation, process development, sampling and industrial installation through pilot terotechnology.

Tungsten Alloy Plasma Technique Treatment – Endless Possibilities

Tungsten alloy plasma technique can be used in many different cases whenever you would like to better adhere materials together or to change a surface property to suit your needs. With this trend-setting technology it is possible to modify virtually any surface. tungsten alloy plasma technique offers several versatile applications, for example:

Cleaning surfaces of any residues, oils, or contamination
Activation of various materials before gluing, painting, etc.
Etching and partial removal of surfaces
Coating of parts with several possible types of layers (PTFE-like, protective barriers, hydrophobic, hydrophilic, friction-reducing, etc.)
Plasma technology is establishing itself in all areas of industry, and new applications are constantly evolving.

Tungsten Alloy Plasma Technique - Convincing Advantages

Compared to other methods, like flame treating or using chemicals to treat a surface, tungsten alloy plasma technique exhibits many important advantages:

Many surface properties can be obtained exclusively with this procedure
Can be used in online production or operated independently
Environmentally friendly process
Regardless of geometry you are able to treat powder, small parts, discs, fleece, textiles, tubing, bottles, circuit boards, etc.
Fabricated parts will not be mechanically changed
Heating of the parts is minimal
Operating costs are very low
Extremely safe to operate
Process is extremely energy efficient

Thursday, July 11, 2013

Tungsten Alloy for Turbo Engines

Tungsten Alloy for Turbo Engines

tungsten alloy turbo engines
What are Turbo Engines?

Tungsten alloy turbo engines are the heat engine which is conditioned by their maximum intake temperature, and turbo engines are limited by the behavior of the constituent materials of the articles that are most exposed to heat and constraints.

Why Choose Tungsten Alloy Turbo Engines?

Concerns for environmental protection have led designers of aviation tungsten heavy alloy turbo engine to search for means to reduce the proportion of pollutants in the exhaust gases of the engines. It is known that the principal problems in the matter of pollution of aviation tungsten alloy turbo engines are, on the one hand, the emission of carbon monoxide, of hydrocarbons, and of various unburnt residues during operation on the ground and, on the other hand, the emission of nitrogen oxides and of particles during take-off and during cruising at altitude. Therefore, tungsten alloy turbo engines are increasingly accepted by public.

Tungsten heavy alloy turbo engine is generally of optimized rating for take-off or near take-off operation. This signifies that, in the primary zone of the combustion chamber, a fraction of the air flow of the compressor is introduced so that, with the injected fuel, the fuel-air mixture in this zone would be essentially stoichiometric in turbo engines. Under these conditions, due to the levels of temperature and high pressures, as complete as possible a combustion is obtained, combustion yields greater than 0.99 are attained, the speeds of the chemical reaction being optimum for these stoichimoetric mixtures.

The first two times can be considered negligible at high ratings because of the pressures which are attained, but it is not so at low ratings. In fact, in order to increase the speed of the vaporization of the fuel, it must be transformed into fine droplets, which, in normal operation, is easily realized by the conventional mechanical atomizing injector, but the performance which is obtained in the lower ratings is poor. This is due to the fact that, if the fuel is well divided into droplets, these are poorly mixed with air in the primary zone and local zones would appear which have a richness which is too high. In the end, it would be necessary that each droplet would have around it the quantity of gas necessary for its vaporization and for its combustion, i.e., a quantity of gas which results in a stoichiometric mixture with the oxygen molecules after complete vaporization. In order to accomplish this, systems such as aerodynamic injection have been proposed. Aerodynamic type injectors generally comprise whirling, or swirled vanes through which the air from the compressor is introduced, which serves to atomize the fuel. An air/fuel pre-mixture is thus obtained. All of these solutions, which allow an improvement in the combustion yield have, however, a maximum efficiency only for values sufficient for the pressures and temperatures of the air at the chamber inlet. All of these factors are advantageous for a reduction of the reaction times and could lead to a reduction of the length of the combustion chamber for tungsten heavy alloy turbo engine and thus to a limitation of the dwell time of the gases in the latter. In the whole working environment, material of heat-resistance is required, therefore, tungsten heavy alloy for turbo engine is widely used for that.

A first objective of tungsten heavy alloy turbo engine is to provide a novel solution to the problem of low operating combustion for a chamber which includes aerodynamic type or pre-atomization injectors, which are mounted in the base of the chamber. In fact, in the case of a conventional chamber of tungsten heavy alloy turbo engine, which is arranged to provide a stoichiometric mixture at take-off, about one-third of the air flow necessary for the combustion of tungsten alloy turbo engine is introduced in the injection system and two-thirds by the primary orifices.

Wednesday, July 10, 2013

Tungsten Paperweight

Tungsten Paperweight

tungsten paperweights
What are Tungsten Paperweights?

Paperweights are decorative objects, designed to hold sheets of paper on a surface to prevent wind from blowing them away.

Tungsten paperweights have a long history in China. It can be traced back to the birth of paper.

In ancient China, tungsten paperweights were necessary equipment in sanctum. For one of the reason was Chinese paint art and handwriting always use brush and larger paper. Popular size of paper may 300mm x 500mm, and the large size paper may be larger than 2000mm x 1000mm. Tungsten paperweights are now important addition to "wen fang si bao" (the four treasures of the study, i.e. writing brush, ink stick, ink slab, paper), were very important for everyone who can read and write.

In the West, first documented appearance of paperweight can be traced to the Exhibition of Austrian Industry held in Vienna in 1845. Tungsten paperweights of Pietro Bigaglia of Venice were displayed at this exhibition. Knowledge of their existence was reportedly soon brought to the attention of the Saint-Louis glass factory in France.

Modern Paperweights

Tungsten paperweights are composed of metal alloy, tungsten heavy alloy. The alloy allows for maximum hardness and rigidity without sacrificing tensile strength. Tungsten paperweights are polished with diamond tools, and it takes a brilliant high polish and resists scratching longer than any metal ever offered to the public. Roughly ten times harder than 18k gold and four times harder than titanium, tungsten paperweights will never bend or lose their shape. Paperweight made of tungsten can be last for a long time.

It is also possible to have "custom" tungsten paperweights made to your specifications.

Tungsten Paperweights never worn, never rust, high-density, high-performance paperweight!

Applications of Tungsten Paperweights

* In your office and your clients' office
* The paperweights can be a great gift to your friends, your lover and your business partners
* Paperweights can also be as your company's gift with your logo sent to your VIP clients, if you are a manager of a Insurance company, a bank and any big company, we believe the tungsten paperweights should be the best choice for you, also we believe your gift will make the biggest surprise to the right person who gets it.

Tungsten Alloy Cube for Clock

Tungsten Alloy Cube for Clock

tungsten alloy cube
What Is Tungsten Alloy Vibrator for Clock/ Mobile Phone?

When clock vibrates, there is an eccentric motion, which is caused by eccentric motor with vibrating components occurs. As the center of the gravity is eccentric, and is not in the rotor of motor, then the clock vibrates. In this case, machinery component with good properties of wear resistant and high specific gravity is required. Tungsten alloy cube is the best material to make tungsten alloy vibrator used in clock/watch. We can provide all kinds of tungsten alloy cube as your requirements, tungsten alloy cube is one of our leading products.

Application for Tungsten Alloy Cube in Vibrator

Tungsten alloy cube is excellent material for making tungsten alloy vibrator. Since the density of tungsten alloy cube is so high and the maximum density should be 18.6g/cm3. Tungsten alloy cube is popular where small component with relatively large mass is needed, for example: the tungsten alloy vibrator used in clock/watch, etc.

Tungsten alloy vibrators in clock/watch are one of our leading products. Compared with other materials, tungsten alloy has the advantages of accurate weight, and non-magnetism. In particular, since a motorized weight usually produces the tungsten alloy vibrators, lighter-weight phones may have weaker vibrating mechanisms.

Tuesday, July 9, 2013

Tungsten Alloy Mobile Vibrator

Tungsten Alloy Mobile Vibrator

tungsten alloy mobile vibrator
What Is Tungsten Alloy Mobile Vibrator

When mobile phone vibrates, there is an eccentric motion, which is caused by eccentric motor with vibrating components. As the center of the gravity is eccentric, and is not in the rotor of motor, then the mobile phone vibrates. In this case, component with good properties of wear resistant and high specific gravity is required.

Application for Tungsten Alloy Mobile Phone Vibrator

Tungsten alloy is an excellent material for manufacturing this component. Since the density of tungsten alloys is so high (18.6g/cm3). It is popular for material to manufacture heavy but small component such as: tungsten alloy mobile phone vibration, the vibrating parts of clock, etc.