The field of this disclosure is related to centrifuge apparatus for separation of fluids by the use of such centrifuges.
Generally, a centrifuge is an apparatus that puts an object in rotation around a fixed axis, applying a potentially strong radial force perpendicular to the axis of spin. The centrifuge works using the sedimentation principle, where centripetal acceleration causes denser substances and particles that are held within the spinning container, to move outward in the radial direction. At the same time, objects that are less dense are displaced and forced toward the axis of spin. In a laboratory centrifuge that uses sample tubes, the radial acceleration causes denser particles to settle to the bottom of the tube, while low-density substances rise to the top. There are three types of centrifuge designed for different applications. Industrial scale centrifuges are commonly used in manufacturing and waste processing to sediment suspended solids, or to separate immiscible liquids. An example is the cream separator found in dairies. Very high-speed centrifuges and ultracentrifuges are able to provide very high accelerations separating fine particles down to the nano-scale, and also molecules of different masses. Gas centrifuges are used for isotope separation, such as to enrich nuclear fuel to obtain fissile isotopes.
A wide variety of laboratory-scale centrifuges are used in chemistry, biology, biochemistry and clinical medicine for isolating and separating suspensions and various fluid substances. They vary widely in speed, capacity, temperature control, and other characteristics. Laboratory centrifuges often can accept a range of different fixed-angle and swinging bucket rotors able to carry different numbers of centrifuge tubes and rated for specific maximum speeds. Controls vary from simple electrical timers to programmable models able to control acceleration and deceleration rates, running speeds, and temperature regimes. Ultracentrifuges spin the rotors under vacuum, eliminating air resistance and enabling exact temperature control. Zonal rotors and continuous flow systems are capable of handing bulk and larger sample volumes, respectively, in a laboratory-scale instrument. An important application in medicine is blood separation. Blood separates into cells and proteins (RBC, WBC, platelets, etc.) and serum. DNA preparation is another common application for pharmacogenetics and clinical diagnosis. DNA samples are purified and the DNA is prepped for separation by adding buffers and then centrifuging it for a certain amount of time. The blood waste is then removed and another buffer is added and spun inside the centrifuge again. Once the blood waste is removed and another buffer is added the pellet can be suspended and cooled. Proteins can then be removed and with further centrifuging DNA may be isolated completely. Protocols for centrifugation typically specify the amount of acceleration to be applied to the sample, rather than specifying a rotational speed, i.e., revolutions per minute. This distinction is important because two rotors with different diameters running at the same rotational speed will subject samples to different acceleration forces.
In circular motion, acceleration is the product of radial distance, the square of angular velocity and the acceleration relative to “g.” This is traditionally referred to as “relative centrifugal force” (RCF). The acceleration is measured in multiples of “g” the standard acceleration due to gravity at the Earth's surface which is a dimensionless quantity given by the radius times the angular velocity squared and divided by “g.”
Embodiments of the described apparatus are illustrated only as examples in the figures of the accompanying drawing sheets wherein the same element appearing in various figures is referenced by a common reference mark.
The invention is a multi-axis centrifuge 5 as shown in
It should be clear to those of skill in the art that outer ring 10 may be eliminated, and instead, in a further embodiment, simply arranged to have inner ring 20, motor 22 with its bearing set 24, and axle 26 supported directly by struts 18.
It should be understood that as hub 15 and outer ring 10 rotate, motor 22 may simultaneously rotate inner ring 20.
As shown in the figures, a spherical capsule 40 may be positioned centrally and concentrically within both inner ring 20 and outer ring 10. Capsule 40 may be hollow so that it may have an interior surface which may be spherical or may have any other shape whatsoever. Capsule 40 may be engaged with inner ring 20 by axle 30, and motor 32 with its bearing set 34. Motor 32 may be able to drive axle 30 and capsule 40 in rotation about the Y axis.
Motors 14, 22, and 32 may be operated independently with any one of said motors rotating or not and each motor may be operated in either rotational sense. Indeed, each motor may be adjusted to a selected rotational velocity and, additionally, each may be operated in any sequence of back and forth rotation according to a present or adjustable program.
The primary objective of centrifuge 5 is the separation of fluid, semi-solid, or solid species as described in the preceding Background. Such species shall be referred to herein as comprised of “particles” which may be small pieces of solid materials, molecules, gaseous or liquid elements, or atomic particles. A further objective may be achieved by applying back and forth agitation programs which can result in the beneficial mixing of species having similar masses while those of differing masses are separated. With effective separation by high speed spinning of capsule 40, interposed with rotational agitation for mixing, both may be accomplished simultaneously.
It should be recognized that the spinning of capsule 40 about only the Y axis using motor 32 will result in separating a material with a gradation of particle masses with heavier masses moving toward the interior surface of capsule 40 forming a torus shape or a flat band, i.e., a ring, of heavy mass particles and such a ring will be circumscribed about the Y axis and lie in the X-Z plane. The ring will have a cross-sectional shape associated with a gaussian profile, that is; the probability density function of a normally distributed random variable. The center will be aligned with the X-Z plane. With higher rotational speeds, the center magnitude will increase and the value of sigma, a measure of the spread, will diminish, i.e., the width of the ring will decrease.
Alternately, if in addition to the rotation of motor 32, motor 22 were to also be operated causing rotation of inner ring 20, heavier mass particles will tend to migrate not only to a ring lying in the X-Z plane, but also to form a ring lying in the Y-Z plane. Assuming the velocities of motors 32 and 22 were equal the heavier mass particles will spread out in association with both the X-Z and the Y-Z planes while lighter mass particles will be displaced toward the X-Y plane. At relatively low rotational velocities, heavier particles will migrate radially and appear to be smoothly spread-out between the X-Z and Y-Z planes. However, as rotational velocities increase two distinct rings will start to form, one associated with each of the X-Z and Y-Z planes. These two rings will achieve total masses in proportion to their respective rotational velocities.
In the same manner as described above, when motors 14, 22, and 32 are operated simultaneously, at slow rotational speeds heavy particles will tend to be uniformly distributed in contact around the entire interior surface of capsule 40. However, as motor rotation increases, separate rings will tend to grow in alignment with the three respective planes X-Y, X-Z, and Y-Z, and at significant rotational velocities, three distinct rings of heavier mass particles will form against the interior surface of capsule 40 while lighter mas particles will tend to align within the interior of each of the three rings with the lightest mass particles positioned at the center.
It is well known in the art to disassemble a centrifuge container such as capsule 40 to retrieve separated materials. This could be accomplished by removing capsule 40 from axle 30 and then separate the two hemispheres to acquire the materials within.
The dashed lines in
In the foregoing description, embodiments are described as a plurality of individual parts, and methods as a plurality of individual steps and this is solely for the sake of illustration. Accordingly, it is contemplated that some additional parts or steps may be added, some parts or steps may be changed or omitted, and the order of the parts or steps may be re-arranged, while maintaining the sense and understanding of the apparatus and methods as claimed.
Number | Name | Date | Kind |
---|---|---|---|
2967329 | Friedland et al. | Jan 1961 | A |
3275733 | Schule et al. | Sep 1966 | A |
3340619 | Bertin | Sep 1967 | A |
3347971 | Mankowich et al. | Oct 1967 | A |
3652760 | Petri | Mar 1972 | A |
3788392 | Suzuki | Jan 1974 | A |
3841165 | Benzing et al. | Oct 1974 | A |
3929182 | Amado, Jr. | Dec 1975 | A |
4050875 | Katzman et al. | Sep 1977 | A |
4104357 | Blair | Aug 1978 | A |
7241114 | Koeppler | Jul 2007 | B2 |
9457398 | Ciardullo | Oct 2016 | B2 |
20110042864 | Naef | Feb 2011 | A1 |
20120301667 | Ryabova | Nov 2012 | A1 |
20160346964 | Nurnberg et al. | Dec 2016 | A1 |
Number | Date | Country |
---|---|---|
1254090 | Nov 1971 | GB |
2543815 | Mar 2017 | GB |
Entry |
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WO, PCT/US2019/026793 ISR and Written Opinion, dated Jul. 5, 2019. |
Number | Date | Country | |
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20210060580 A1 | Mar 2021 | US |