The gas centrifugation process uses a unique design that allows gas to constantly flow in and out of the centrifuge. Unlike most centrifuges which rely on
batch processing, the gas centrifuge uses continuous processing, allowing cascading in which multiple identical processes occur in succession. The gas centrifuge consists of a cylindrical rotor, a casing, an
electric motor, and three lines for material to travel. The gas centrifuge is designed with a casing that completely encloses the centrifuge. The cylindrical rotor is located inside the casing, which is
evacuated of all air to produce a near frictionless rotation when operating. The motor spins the rotor, creating the centrifugal force on the components as they enter the cylindrical rotor. This force acts to separate the molecules of the gas, with heavier molecules moving towards the wall of the rotor and the lighter molecules towards the central axis. There are two output lines, one for the fraction enriched in the desired isotope (in uranium separation, this is 235U), and one depleted of that isotope. The output lines take these separations to other centrifuges to continue the centrifugation process. The process begins when the rotor is balanced in three stages. Most of the technical details on gas centrifuges are difficult to obtain because they are shrouded in "nuclear secrecy". Inducing a countercurrent flow uses
countercurrent multiplication to enhance the separative effect. A vertical circulating current is set up, with the gas flowing axially along the rotor walls in one direction and a return flow closer to the center of the rotor. The centrifugal separation continues as before (heavier molecules preferentially moving outwards), which means that the heavier molecules are collected by the wall flow, and the lighter fraction collects at the other end. In a centrifuge with downward wall flow, the heavier molecules collect at the bottom. The outlet scoops are then placed at the ends of the rotor cavity, with the feed mixture injected along the axis of the cavity (ideally, the injection point is at the point where the mixture in the rotor is equal to the feed). This countercurrent flow can be induced mechanically or thermally, or a combination. In mechanically induced countercurrent flow, the arrangement of the (stationary) scoops and internal rotor structures are used to generate the flow. A scoop interacts with the gas by slowing it, which tends to draw it into the centre of the rotor. The scoops at each end induce opposing currents, so one scoop is protected from the flow by a "baffle": a perforated disc within the rotor which rotates along with the gas—at this end of the rotor, the flow will be outwards, towards the rotor wall. Thus, in a centrifuge with a baffled top scoop, the wall flow is downwards, and heavier molecules are collected at the bottom. Thermally induced
convection currents can be created by heating the bottom of the centrifuge and/or cooling the top end.
Separative work units The
separative work unit (SWU) is a measure of the amount of work done by the centrifuge and has units of mass (typically
kilogram separative work unit). The work W_\mathrm{SWU} necessary to separate a mass F of feed of assay x_{f} into a mass P of product assay x_{p}, and tails of mass T and assay x_{t} is expressed in terms of the number of separative work units needed, given by the expression :W_\mathrm{SWU} = P \cdot V\left(x_{p}\right)+T \cdot V(x_{t})-F \cdot V(x_{f}) :where V\left(x\right) is the
value function, defined as :V(x) = (1 - 2x) \cdot \ln\left(\frac{1 - x}{x}\right)
Practical application of centrifugation Separation of uranium-235 from uranium-238 The separation of uranium requires the material in a gaseous form;
uranium hexafluoride (UF6) is used for
uranium enrichment. Upon entering the centrifuge cylinder, the UF6 gas is rotated at a high speed. The rotation creates a strong centrifugal force that draws more of the heavier gas molecules (containing the 238U) toward the wall of the cylinder, while the lighter gas molecules (containing the 235U) tend to collect closer to the center. The stream that is slightly enriched in 235U is withdrawn and fed into the next higher stage, while the slightly depleted stream is recycled back into the next lower stage.
Separation of zinc isotopes For some uses in nuclear technology, the content of
zinc-64 (64Zn) in
zinc metal has to be lowered in order to prevent formation of
radioisotopes by its
neutron activation.
Diethyl zinc is used as the gaseous feed medium for the centrifuge cascade. An example of a resulting material is
depleted zinc oxide, used as a
corrosion inhibitor. ==See also==