TITLE OF THE INVENTION
AUTOMATIC SOLIDS DISCHARGE TUBULAR BOWL CENTRIFUGE
CROSS REFERENCE TO RELATED APPLICATIONS This application claims priority under 35 U.S.C. §119 (e) to provisional patent application serial number 60/223,409 filed August 4, 2000; and to utility patent application serial number 09/896,551 filed June 29, 2001.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT
N/A
BACKGROUND OF THE INVENTION The present invention generally relates to centrifuges and in particular to a centrifuge enabling automatic discharge of solids from a separated centrate.
Many different types of centrifugal separators are known for separating heterogeneous mixtures according to "their specific gravities components" . A heterogeneous mixture, which may also be referred to as feed material or liquid feed, is injected into a rotating bowl of the separator. The bowl rotates at high speeds and forces particles of the mixture to separate from the liquid centrate. As a result, a dense solids cake compresses tightly against the surface of the bowl and the liquid centrate forms radially inward from the solids cake.
The bowl may rotate at speeds sufficient to produce 20,000 g' s so that the solids may be separated from the
centrate. Typically, the liquid feed travels at a relatively slow speed before being introduced through feed holes to the rotating bowl where the liquid feed is instantaneously accelerated to the angular speed of the rotating bowl. However, introducing the liquid feed to the bowl at such high speeds creates shear forces that often destroy a large amount of the solid component of the liquid feed before separation.
While the solids accumulate along the wall of the bowl, the centrate is drained. Once it is determined that a desired amount of the solids has been accumulated, the separator is placed in a discharge mode. In one such discharge mode, a scraper blade extending the length of the rotating bowl is placed in a scraping position against the separator wall and the bowl is rotated at a low scraping speed. Then, the solids are scraped from the sides of the bowl and fall toward a solids collecting outlet. However, such scraping systems do not effectively remove wet or sticky solids which may have the consistency of peanut butter. In such instances, the sticky solids remain stuck on the separator wall and scraper blades or fall from the wall and then reattach to the blades before reaching the collecting outlet. As a result, the solids recovery yield is reduced and the remaining solids undesirably contaminate the separator.
BRIEF SUMMARY OF THE INVENTION
In accordance with the present invention, a centrifugal separator is provided which automatically discharges solids and maximizes the amount of solids recovery yield and the dryness of the separated solids with minimal user intervention. Full hermetic containment of the separation
process is achieved by this centrifugal separator so that automatic "clean in place" (C.I. P.) and "sterilization -in place" (S.I. P.) operations may be performed. Accordingly, the centrifugal separator of the present invention is able to perform a wide range of liquid/solid and liquid/liquid separations in biotechnology, pharmaceutical, chemical, food and beverage, and other industrial processes.
The centrifugal separator includes a rotatable separator bowl supported by a hollow shaft spindle. The shaft spindle also supports and positions a scraper and feed assembly for axially moving within the separator bowl. The scraper and feed assembly includes a plurality of scraper blades having a small surface area that extend to substantially the interior surface of the separator bowl. A feed liquid is supplied to the separator bowl by liquid feed passages which pass through the shaft spindle to the scraper and feed assembly so that the feed liquid exits proximate the ends of the scraper blades at substantially the interior surface of the separator bowl. This prevents the feed liquid from being instantaneously over-accelerated due to the angular velocity of the separator bowl. As a result, the feed liquid is subjected to shear forces that are greatly reduced and the feed liquid is less likely to be harmed as compared to the prior art. The separator bowl is preferably a tubular bowl having a relatively small diameter and a long length. By the use of such tubular separator bowls, high speed operations of the centrifugal separator may be performed to generate separation forces as high as 30,000 g' s at the interior surface of the separator bowl. This allows the feed liquid to be safely and effectively separated at lower stress levels within the separator bowl.
As a result of the high speed operation, the centrifugal separator is able to more effectively separate the solids from the residual liquid so that the dryness of the accumulated solids cake is increased. Even though the scraper blades have a relatively small surface area, the solids from the walls of the separator bowl may be more easily and effectively scraped. To scrape and discharge all of the accumulated solids, the scraper and feed assembly is slowly raised then lowered while the separator bowl is slowly rotated. By the combination of the accumulated solids being drier and the scraper blades having a small scraping surface area, the amount of the discharged solids is greatly increased. The centrifugal separator according to the present invention may thereby be operated aseptically and provide C.I. P. or S.I. P. operations.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING
The invention will be more fully understood by reference to the following detailed description of the invention in conjunction with the drawings, of which:
Fig. 1 illustrates a centrifugal separator according to an embodiment of the present invention;
Fig. 2 is a transparent view of a scraper and feed assembly according to an embodiment of the present invention;
Fig. 3 illustrates the operation of a centrifugal separator in a feed mode according to an embodiment of the present invention;
Fig. 4 illustrates the operation of a centrifugal separator in a drain mode according to an embodiment of the present invention;
Fig. 5 illustrates the operation of a centrifugal separator in a scrape mode according to an embodiment of the present invention; and
Figs. 6A and 6B illustrate a centrifugal separator utilizing a feed cone in another embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
A centrifugal separator 100 according to one embodiment of the present invention is illustrated in Fig. 1. The centrifugal separator 100 includes a cylindrical separator bowl 110, preferably a conventional tubular type bowl having a relatively small diameter D and a long length L such that the ratio of L/D is approximately 5/1. For example, a separator bowl 110 having a bowl diameter up to 500mm and a flow capacity up to 100<! /min. may be used so that sufficient rotational speeds may be achieved at the interior surface of the separator bowl 110 to generate separation forces from 20,000 g' s to 30,000 g's. Tubular type bowls provide cost and performance advantages over other known cylindrical bowls, such as "basket" type centrifuge bowls, for similar pool areas and gravitational forces. For instance, because the radius of the tubular bowls are much smaller, lower peripheral velocity results which reduces windage, friction and heat generation. Also, the longer length of the tubular bowl provides better liquid stability because axial liquid waves are damped out.
A scraper and feed assembly 120 is operatively connected to a hollow scraper shaft spindle 130 within the separator bowl 110. The scraper shaft spindle 130 extends out from the separator bowl 110 to a feed pipe 140. A scraper shaft seal 132 is positioned where the scraper shaft
130 extends from the separator bowl 110 to prevent liquids and solids from escaping the separator bowl 110. A rotary union 142 connects the feed pipe 140 to the scraper shaft spindle 130 so that the liquid feed may be injected into the separator bowl 110.
A variable speed drive motor 150 is connected to a main bearing assembly 134 of the scraper shaft spindle 130 by a drive belt 152. The drive motor 150 is controllably operated in conjunction with a scraper shaft clutch 136 to rotate the separator bowl 110 at the desired speeds for separating the liquid feed. A scraper actuator piston 126 is also operatively connected to the scraper shaft spindle 130 in combination with the scraper shaft clutch 136 for raising and lowering the scraper and feed assembly 120 within the separator bowl 110. In a discharge mode, the scraper shaft clutch 136 is engaged for holding the scraper shaft spindle 130 stationary and slowly rotating the separator bowl 110 at a low scraping speed so that scraper blades maintain contact and scrape solids from the walls of the separator bowl 110. In other operating modes, the scraper shaft clutch 136 is disengaged so that the scraper and feed assembly 120 rotates at the same speed and in the same direction as the separator bowl 110 (i.e., the scraper and feed assembly 120 is stationary relative to the separator bowl 110) .
A more detailed view of the scraper and feed assembly 120 is shown in Fig. 2. Fig. 2 illustrates three axial scraper blades 122 attached to the scraper and feed assembly 120. It should be appreciated that the scraper and feed assembly 120 may be designed with a varying number of scraper blades 122 depending on the surface area of the
separator bowl 110 that is desired to be scraped while maintaining a stable and high speed rotation.
The scraper and feed assembly 120 includes liquid feed passages 124 that channel the feed liquid from the scraper shaft spindle 130 and through the scraper and feed assembly 120 to first and second outer feed holes 126 and 128 on the scraper blades 122 so that the liquid feed is ejected at the surface of the separator bowl 110. The coriolis force due to the rotation of the scraper and feed assembly 120 causes the feed liquid to accelerate towards the first outer feed hole 126 at the surface of the separator bowl 110. If the feed liquid is prevented from exiting at the first outer feed hole 126 due to an accumulation of solids or other means, the liquid may exit at the second outer feed hole 128 with substantial acceleration towards the surface of the separator bowl 110. By ejecting the feed liquid away from the scraper and feed assembly 120 and towards the surface of the separator bowl 110, the liquid is more gradually accelerated and is prevented from being instantaneously accelerated due to the angular velocity at which the bowl is rotating. Thereby, the shear forces to which the feed liquid are subjected are greatly reduced so that the feed liquid is less likely to be damaged.
It is to be noted that in the illustrated embodiment of Fig. 2, drill holes formed on the surface of the scraper and feed assembly 120 during the creation of the feed passages 124 are subsequently filled. Other fabrication techniques may obviate the need for drilling and filling these surface holes. In accordance with the operation of the centrifugal separator 100, a feed mode for the liquid feed will be described with reference to Fig. 3. In the feed mode, the
feed liquid is introduced through the feed pipe 140. The scraper clutch 136 is disengaged so that the scraper shaft spindle 130 is free to rotate with the separator bowl 110. The feed liquid flows from the feed pipe 140 through the scraper shaft seal 132 to the scraper shaft spindle 130 in the direction shown by the arrows. The feed liquid continues through the feed passages 124 of the scraper and feed assembly 120 and enters the separator bowl 110 at its outer surface. Due to the centrifugal force, the liquid flows up the pool surface of the separator bowl 110. Any overflow feed liquid decants over a weir 182 as clarified liquid (centrate) at the top of the separator bowl 110 and then flows into a centrate case 180. As the liquid flows through the separator bowl 110, it is clarified of entrained solid particles by the high centrifugal force acting upon the liquid. The solids are forced to settle on the inside wall of the separator bowl 110 and collect as a compressed solids cake as a result of the centrifugal force.
Because the scraper clutch 136 is not engaged, the separator bowl 110 and the scraper and feed assembly 120 rotate together in the same direction at a high speed, for example in a clockwise direction as indicated by the arrow. Accordingly, the liquid feed passing through the scraper shaft 130 is gradually accelerated through the feed passages 124 to the angular velocity of the scraper and feed assembly 120. As the separator bowl 110 rotates, solids 184 collect along the surface of the separator bowl 110 and a rotating liquid pool 186 forms inward from the solids 184.
Next, the centrifugal separator 100 is placed in a bowl drain mode as shown in Fig. 4 when the separator bowl 110 has been determined to be sufficiently full of solids, usually by the turbidity of the centrate. The liquid feed
is shut off and then the bowl driver electronically brakes the separator bowl 110 to a full stop. The residual liquid in the separator bowl 110 drains into a residual liquid cup 160 while the solids remain on the surface of the separator bowl 110. The residual liquid cup 160 is preferably provided with a shaped bottom surface for channeling the residual liquid to a residual liquid discharge port 162 located at the bottom of the residual liquid cup 160 for transport of the residual liquid back to liquid feed storage (not shown) . The bowl drain mode may also include a step of rotating the separator bowl 110 briefly at a high speed to further drain liquid from the accumulated solids . After this optional spinning step, the solids become drier which improves the efficiency of the subsequent scraping steps. When the separator bowl 110 has been completely drained of residual liquid, the centrifugal separator 100 as shown in Fig. 5 enters a scrape mode. The residual liquid cup 160 swings away from the bottom of the separator bowl 110 so that a solids discharge port 170 is positioned beneath the bowl 110 to collect falling solids without mixing with the residual liquid.
The scraper shaft 130 is engaged by the scraper clutch 136 to prevent the scraper shaft 130 from rotating. The separator bowl 110 rotates slowly in an opposite direction from the feed mode (in a counter clockwise direction as shown by the arrow in Fig. 5) . Then, the scraper actuator 126 slowly draws up the scraper shaft 130 and the scraper and feed assembly 120 up towards the top of the separator bowl 110 as indicated by the arrows. The solids cake is scraped from the walls of the separator bowl 110 and towards the center of the separator bowl 110 so that the scraped solids are free to fall out of the discharge port 170 and
into a receiving container (not shown) . After the scraper and feed assembly 120 reaches the reversing point near the top of the separator bowl 110, the scraper actuator 126 reverses in direction so that the scraper shaft 130 and the scraper and feed assembly 120 descend toward the bottom of the separator bowl 110. The scraping process continues until the stopping point near the bottom of the separator bowl 110 is reached. It is appreciated that the solids scraping from the separator bowl 110 can be performed in either direction (both counter clockwise and clockwise) .
In another embodiment of the invention, a centrifugal separator 200 having an alternative liquid feed path is shown in Figs. 6A and 6B. A feed cone 200 positioned at the bottom of the separator bowl 110 is used to feed liquid up into the separator bowl 110. The feed cone 200 is caused to rotate by plastic pins 204 on the feed cone 200 and metal vanes 202 on the separator bowl 110. This method of rotating the feed cone 200 with the separator bowl 110 allows the separator bowl 110 to go through mild oscillations; the separator bowl 110 maintains its center of rotation while being filled with liquid and is not restricted by the feed cone 200. The feed liquid is injected through a feed port 230 when the feed cone 200 is positioned in an upper connect position to the separator bowl 110 for a feed mode. A positioning mechanism 220, including bearings, shaft seals, and an actuator piston, is used to raise and lower the feed cone 200 between the feed mode as illustrated in Fig. 6A and a liquid drain mode as illustrated in Fig. 6B. In the drain mode the feed cone 200 is lowered by the positioning mechanism so that residual liquid may drain down from the separator bowl 110 through a residual liquid port 240. Subsequently, the feed cone 200
is pivoted from beneath the separator bowl 110 to enable scraped solids to fall into the solids discharge port 170.
The liquid feed apparatus of Figs. 1-5 or of Figs. 6A and 6B can also be used for the purpose of cleaning the centrifuge and associated elements through the introduction of appropriate liquid cleaning agents in the liquid feed path.
In a preferred embodiment, all of the separating, draining and scraping operations take place in a sealed environment, enabling operation at various pressures and temperatures. Contamination is thereby minimized.
It is understood that a variety of control mechanisms with suitable human and/or computer interfaces are preferably provided for the purpose of automating the filling, draining and scraping operations. Manual operation may be alternately enabled through the provision of various actuators .
It will be apparent to those skilled in the art that other modifications to and variations of the above- described techniques are possible without departing from the inventive concepts disclosed herein. Accordingly, the invention should be viewed as limited solely by the scope and spirit of the appended claims .