Tungsten has a very wide range of appliactions in a variety of industries that make it a highly used element. Tungsten is a hard, grey coloured metal, which is one of the heaviest elements. It has a melting point of 3,422 degrees Celsius – the highest of all the elements – and a boiling point of 5,555 degrees Celsius. The element is found naturally on Earth in only chemical compounds.
Tungsten is very brittle and difficult to work due to the weak grain boundaries present in its polycrystalline form. In order to make the element more pliable, single-crystalline tungsten can be used, making it easier to draw, forge and extrude the material.
The two crystallographic forms in which tungsten exists are α and β. The α form is body centered cubic and is the more stable of the two. It is a low superconductor, showing exactly zero resistance to electrical currents, and the expulsion of magnetic fields once it reaches below its ‘critical temperature’. The β form of tungsten is a metastable structure, which exists in columnar grains, rather than the isometric grains of the α form. This allows the element to be more pliable. The β phase exists in a crystallographic structure called A15 cubic.
By mixing together the two different crystallographic forms of tungsten (α and β), it increases the superconducting transition temperature TC above that of the stable α form. Alloying tungsten with other metals can also produce an increase in the superconducting transition temperature, making such alloys useful in superconducting circuits in low temperatures.
Tungsten has the ability to maintain its strength in high temperatures. It has inertness to oxygen, acids and alkalis, and has a very high density (19.3 grams per cubic centimeter). It has the lowest vapour pressure, the highest tensile strength and the lowest coefficient of expansion of any pure metal.
There are several uses for tungsten that take advantage of its key properties. The main application being its use in filaments; ranging from your regular household light bulb through to filaments in X-ray tubes and electron microscopes. Tungsten is the ideal material choice for the filament because it has the highest melting, the lowest vapour pressure, the lowest coefficient of thermal expansion, the highest tensile strength of all the metals and an ability to maintain this strength at high temperatures.
Tungsten's high density and hardness also makes it useful in military applications such as rocket engine nozzles. Tungsten's high desnity also makes it a good choice for creating shields to gamma radiation.
Tungsten WOVEN Mesh/Gauze
|Line Number & Material||Dimensions||Purity||Description|
|W5570 Tungsten WOVEN Mesh/Gauze||150 mesh per inch||99.95%||3487/sq.cm. Plain weave. Wire diameter 0.020mm. |
Aperature: 0.15 mm
Open Area: 77.4%
|W5593 Tungsten WOVEN Mesh/Gauze||100 mesh per inch||99.95%||1550/sq.cm. Plain weave. Wire diameter 0.025mm. |
Aperature: 0.23 mm
Open Area: 81%
|W5594 Tungsten WOVEN Mesh/Gauze||100 mesh per inch||99.95%||1550/sq.cm. Plain weave. Wire diameter 0.050mm. |
Aperature: 0.2 mm
Open Area: 64%
|W5600 Tungsten WOVEN Mesh/Gauze||50 mesh per inch||99.95%||387/sq.cm. Plain weave. Wire diameter 0.025mm. |
Aperature: 0.483 mm
Open Area: 90.3%
|W5613 Tungsten WOVEN Mesh/Gauze||50 mesh per inch||99.95%||387/sq.cm.Plain weave. Wire diameter 0.050mm. |
Aperature: 0.457 mm
Open Area: 81%
|W5614 Tungsten WOVEN Mesh/Gauze||20 mesh per inch||99.95%||62/sq.cm. Plain weave. Wire diameter 0.125mm. |
Aperature: 1.143 mm
Open Area: 81%
|W5615 Tungsten WOVEN Mesh/Gauze||20 mesh per inch||99.95%||62/sq.cm. Plain weave. Wire diameter 0.178mm. |
Aperature: 1.092 mm
Open Area: 74%