A centrifuge gets its name from centrifugal force -- the virtual force that pulls spinning objects outward. Centripetal force is the real physical force at work, pulling spinning objects inward. Spinning a bucket of water is a good example of the forces at work. If the bucket spins fast enough, the water is pulled into it and doesn't spill. If the bucket is filled with a mixture of sand and water, spinning it produces centrifugation. According to the sedimentation principle, both the water and sand in the bucket will be drawn to the outer edge of the bucket, but the dense sand particles will settle to the bottom, while the lighter water molecules will be displaced toward the center.
The centripetal acceleration essentially simulates higher gravity, however, it's important to keep in mind the artificial gravity is a range of values, depending on how close an object is to the axis of rotation, not a constant value. The effect is greater the further out an object gets because it travels a greater distance for each rotation.
Types and Uses of Centrifuges
The types of centrifuges are all based on the same technique but differ in their applications. The main differences between them are the speed of rotation and the rotor design. The rotor is the rotating unit in the device. Fixed-angle rotors hold samples at a constant angle, swinging head rotors have a hinge that allows sample vessels to swing outward as the rate of spin increases, and continuous tubular centrifuges have one chamber rather than individual sample chambers.
Very high-speed centrifuges and ultracentrifuges spin at such a high rate that they can be used to separate molecules of different masses or even isotopes of atoms. For example, a gas centrifuge may be used to enrich uranium, as the heavier isotope is pulled outward more than the lighter one. Isotope separation is used for scientific research and to make nuclear fuel and nuclear weapons.
Laboratory centrifuges also spin at high rates. They may be large enough to stand on a floor or small enough to rest on a counter. A typical device has a rotor with angled drilled holes to hold sample tubes. Because the sample tubes are fixed at an angle and centrifugal force acts in the horizontal plane, particles move a tiny distance before hitting the wall of the tube, allowing dense material to slide down. While many lab centrifuges have fixed-angle rotors, swinging-bucket rotors are also common. These machines are used to isolate components of immiscible liquids and suspensions. Uses include separating blood components, isolating DNA, and purifying chemical samples.
Medium-size centrifuges are common in daily life, mainly to quickly separate liquids from solids. Washing machines use centrifugation during the spin cycle to separate water from laundry, for example. A similar device spins the water out of swimsuits.
Large centrifuges may be used to simulate high-gravity. The machines are the size of a room or building. Human centrifuges are used to train test pilots and conduct gravity-related scientific research. Centrifuges may also be used as amusement park "rides". While human centrifuges are designed to go up to 10 or 12 gravities, large diameter non-human machines can expose specimens to up to 20 times normal gravity. The same principle may one day be used to simulate gravity in space.
Industrial centrifuges are used to separate components of colloids (like cream and butter from milk), in chemical preparation, cleaning solids from drilling fluid, drying materials, and water treatment to remove sludge. Some industrial centrifuges rely on sedimentation for separation, while others separate matter using a screen or filter. Industrial centrifuges are used to cast metals and prepare chemicals. The differential gravity affects the phase composition and other properties of the materials.