CA2049199A1 - Sedimentation centrifuge - Google Patents
Sedimentation centrifugeInfo
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- CA2049199A1 CA2049199A1 CA 2049199 CA2049199A CA2049199A1 CA 2049199 A1 CA2049199 A1 CA 2049199A1 CA 2049199 CA2049199 CA 2049199 CA 2049199 A CA2049199 A CA 2049199A CA 2049199 A1 CA2049199 A1 CA 2049199A1
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Abstract
ABSTRACT OF THE DISCLOSURE
A sedimentation centrifuge includes a bowl which is supplied with a feed mixture, i.e., a solid-liquid mixture, from a supply pipe. When the bowl rotates at high speed, heavy solids are displaced radially outwardly toward and sedimented on the inner wall surface of the bowl. The solid particles are then discharged through a discharge hole of the bowl and an outlet passage by a screw conveyor in the bowl. During rotation of the bowl, fins on the screw conveyor assist in separating the liquid into heavy and light liquid phases with increased separation efficiency. The separated heavy and light liquids are separately discharged from the bowl through respective outlet passages.
A sedimentation centrifuge includes a bowl which is supplied with a feed mixture, i.e., a solid-liquid mixture, from a supply pipe. When the bowl rotates at high speed, heavy solids are displaced radially outwardly toward and sedimented on the inner wall surface of the bowl. The solid particles are then discharged through a discharge hole of the bowl and an outlet passage by a screw conveyor in the bowl. During rotation of the bowl, fins on the screw conveyor assist in separating the liquid into heavy and light liquid phases with increased separation efficiency. The separated heavy and light liquids are separately discharged from the bowl through respective outlet passages.
Description
2049~99 SEDIM~NTATION CENTRIFUGE
BACKGROUND OF THE INVENTION
Field of the Invention:
The present invention relates to a sedimentation centrifuge for separating a mixture of solid particles and liquids into solid and liquid phases, and more par-ticularly to a sedimentation centrifuge for separating a mixture of solid particles and two liquid phases, i.e., heavy and light liquids, into the solid particles, the heavy liquid, and the light liquid.
Description of the Prior Arts Heretofore/ centrifuge~ or centrifugal separa-tors are used to separate a mixture of solid particles and liguids into aolid and liquid phases, or a mixture of solid particles and heavy and light liquids into the solid particles, the heavy liquid, and the light liqu~d.
Disk decanters (also called cone-disk decanters) which are in general use for centrifugal sedimentation have a number of spaced conical disks in the form of truncated cones. When a feed slurry of solid-liquid mixture with a large solid content is separated by a disk decanter, however, accumulated solid particles in the mixture tend to clog the gaps between the disks, making 2 210 49~ 9~
the disc decanter fail to operate. To prevent such a problem from happening, it is necessary to reduce the ~mount of solid particles contained in the mixture with, for example, a screw decanter, and then separate the mixture into solid and liquid phases with a disk decant-er. However, this practice requires two expensive de-canters connected in series with each other. Further-more, since the mixture has to be processed under inten-sive centrifugal force twice, the energy consumed by the decanters is relatively large and wasteful.
The inventor has proposed a sedimentation cen-trifuge for ~eparating a mixture of solid particles and liquids into solid and liquid phases, and also a sedimen-tation centrifuge for separating a mixture of ~olid particles and two liquid phases, i.e., heavy and light liquids, into the solid particles, the heavy liquid, and the light li~uid, as disclo~ed in Japanese Patent No.
1,007,732 (Japanese Patent laid-Open No. 054961/75) and Japanese Patent Laid-Open No. 152556/87. The proposed sedimentation centrifuges, which may be termed doubly-canted screw decanters, have a frustoconical bowl for discharging sedimented solid particles. The bowl has an inner wall surface that is canted with respect to the central axis of the bowl first at a larger angle and then at a smaller angle along the direction in which the accumulated solids are discharged. The doubly-canted inner wall surface of the bowl allows the solids to travel smoothly to the end of the bowl and also allows liquid to be removed smoothly from the solid particles.
The bowl structure also serves to increase the amount of feed that stays in the centrifuge for an increased period of time. Therefore, the separation accuracy of the centrifuge and the processing capacity of the centrifuge per unit time are increased.
The inventor has found that much re~mains to be improved in terms of the processing capacity, the separa-tion accuracy, and the amount of required energy in the practical application of the centrifuges. More specifi-cally, as described above, the disk decanter often fails to operate becau~e ~edimented ~olidg tend to clog the gap~ between the disks particularly when feed has a large solid content. This trouble can only be avoided by first reducing the ~olid content in the slurry with the screw decanter and then processing the slurry with the disk decanter. Therefore, the two expensive decanters or centrifuges need to be connected in series with each other, resulting in a wasteful consumption of energy as intensive centrifugal forces are required to be applied twice in the decanters. While the doubly canted screw decanters proposed by the inventor can finish the sepa-rating process when the slurry passes through the centri-fuge only once, the actual use of the proposed decanters has indicated that the proposed decanters are not so advantageous as expected over the series-connected ~en-t;rifugal separators and need further improvement with respect to the processing capacity and the energy con-sumption in applications which demand accurate phase separation.
SUMMARY OF THE INVENTION
It is an ob~ect of the present invention to provide a sedimentation centrifuge which is free of failures due to clogging caused by a slurry or mixture with a large solid content, can separate a slurry with high separation accuracy, consumes a relatively reduced amount of energy, and can ~eparate a relatively large amount of feed highly reliably in only a single cycle of application of centrifugal forces.
According to the present invention, there is provided a sedimentation centrifuge comprising a hollow cylindrical body rotatable about its own central axis, supply means for supplying a solid-liquid mixture into the hollow cylindrical ~ody, a first hollow frustoconical section having an inner wall surface inclined at a larger angle to the central axis, the first hollow frustoconical section having a larger-diameter open end contiguously joined to one end of the hollow cylindrical body and a smaller-diameter open end axially opposite to the Z ~ 9 larger-diameter open end, a second hollow frustoconical section having an inner wall surface inclined at a small-er angle to the central axis, the second hollow frusto-conical section having one open end contiguously joined to the smaller-diameter open end of the first hollow frustoconical section and an opposite open end defining a discharge hole, the one open end being positioned at the same level as or below the free liquid surface of the solid-liquid mixture which is of a cylindrical shape in the hollow cylindrical body while the hollow cylindrical body is rotating, a screw conveyor disposed in the hollow cylidnrical body and the first and second hollow frusto-conical sections for transferring sedimented solids separated from the solid-liquid mixture in the hollow cylindrical body through the first and second hollow frustoconical sections to the discharge hole, bank means on an end of the hollow cylindrical body remote from the discharge hole for controlling an overflow of liquids separated from the solid-liquid mixture, discharge means for discharging the overflow of liquids, and at least one fin mounted on the screw conveyor and di~posed in spaces between turns of the vane of the screw conveyor, the fin being inclined with respect to the central axis.
The bank means may comprise a first bank on an end of the hollow cylindrical body remote from the dis-charge hole for controlling an overflow of a heavy liquid 2 ~ 9 separated from the solid-liquid mixture, and a second bank on an end of the hollow cylindrical body remote from the discharge hole, for controlling an overflow of a light liquid separated from the solid-liquid mixture.
The discharge means may discharge the overflows of heavy and light liquids, respectively. For the purpose of discharging liquids, skimming method is also applicable.
The above and other objects, features, and advantages of the present invention will become apparen~
from the following description when taken in conjunction with the accompanying drawing~ which illustrate preferred embodiments of the present invention by way of example.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic longitudinal crosg-sec~ional view of a sedimentation centrifuge according to the present invention;
FIG. 2 is an enlarged fragmentary longitudinal cross-sectional view of fins and a screw conveyor in the sedimentation centrifuge shown in FIG. l; and FIG. 3 is an enlarged fragmentary longitudinal cross-sectional view of fins and a screw conveyor accord-ing to another embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFE~RED EMBODIM~NTS
As shown in FIG. 1, the three~phase separator 2~Æ9~99 has a supply pipe 1 which extends a~ially into and is open in a large-diameter cylindrical section of a bowl 2 which comprise~ a hollow cylindrical ~ody. A feed slurry or solid-liquid mixture to be separated, which is typi-cally composed of solids and heavy and light liquids, is fed through the supply pipe 1 and holes 12 into the bowl' 2 while the bowl 2 is rotating at high speed. Solid particles contained in the mixture are displaced radially outwardly toward the inner wall surface of the bowl 2 under centrifugal forces which are generated due to the high-speed rotation of the bowl 2.
The bowl 2 ha~ an open discharge end 4 around the supply pipe 1, the open di~charge end 4 defining a d~cgarge hole. The bowl 2 hou~es a screw conveyor 3 which is dispo8ed concentrically therein and extends axially between opposite ends of the bowl 2. The solid particles sedimented on the inner wall surface of the bowl 2 are transferred toward the discharge hole by the screw conveyor 3 which rotates at a speed different from the speed at which the bowl 2 is rotating. The solid particles are then discharged from the discharge hole through an outlet passage 5 out of the three-phase sepa-rator.
The bowl 2 has a doubly-canted portion disposed partly around one end portion of the screw conveyor 3 which is disposed around the supply pipe ~. The doubly-canted portion includes a first frustoconical sectionwhose inner wall surface is inclined at a larger angle to the central axis of the bowl 2 and which has a larger-diameter open end contiguously ~oined to one end of the cylindrical section of the bowl 2, and a second frusto-conical section which has a larger-diameter open end contiguously joined to a smaller-diameter open end of the first frustoconical section and whose inner wall surface is inclined at a smaller angle to the centr~al axis of the bowl 2. The larger-diameter open end of the second frustoconical section is positioned at the same level as or below the free liquid surface or the free surface of the solid-liquid mixture which i~ o a cylindrical shape formed while the bowl 2 i8 rotating. The opposite open end of the ~econd frustoconical section serves as the discharge end 4.
The second frustoconical section includes a beach 6 di~posed near the discharge end 4 and positioned above the level of the mixture in the bowl 2.
Immediately before the sedimented solid parti-cles reach the discharge end 4, the solid particles pass over the beach 6 where remaining li~uid is substantially removed from the solids.
The three-phase separator also includes a plu-rality of helical fins 7 exten~i~g parallel to and posi-tioned between the turns of the flight (vane) of the screw conveyor 3, the fins 7 being mounted on the screw conveyor shaft. The fins 7 are inclined with respect to the central axis of the bowl 2, i.e., the free liquid surface of the solid-liquid mixture of cylindrical shape in the bowl 2 during high-speed rotation thereof. A sub stantial portion of the mixture supplied to the separ~tor flows along the flight of the screw conveyor 3 and the fins 7, and hence is subjected to resistance due to the friction therewith. Therefore, the mixture tends to flow in a region near the inner wall surfacQ of the bowl 2 around the screw conveyor 3 and the fins 7. Since the region near the inner wall surface of the bowl 2 i8 ~paced remotely from the axi~ about which the screw conveyor 3 and the fin~ 7 rotate, the mixture flowing in the reg~on is sub~ected to large centrifugal forces, and can be separated highly efficiently.
The three-phase ~eparator may have one or more helical fins and up to 20 helical fins. The distance between the radially outer tips of the fins and the inner wall surface of the bowl 2 ranges from 5 mm to 100 mm, and each of the fins has a thickness in the range of from 0.5 mm to 2 mm.
The distance between the fins should be as ~mall as possible to reduce the distance that the particles of the mixture have to traverse, i.e., the sedimentation distance, resulting in an increase in the efficiency of 2~
jeimentation. If the distance between the fins were too small, the gaps betwe~n the fins would tend to be clogged by solid particles, preventing solids from being dis-charged from between the fins. Therefore, the distanvce between the fins should be determined depending on the nature of the solid-liquid mixture to be processed.
If the solid-liquid mixture has a larger solid content, then the distance between the radially outer tips of the fins and the inner wall surface of the bowl 2 should preferably be larger. If the solid-liquid mixture has a smaller solid content, then the distance between the radially outer tips of the fins and the inner wall surface of the bowl 2 should preferably be smaller to give the fins an increased unctional surface area for high separation efficiency.
It is therefore preferable that a plurality of screw conveyors with fins of different radial lengths be available, and one of the available screw conveyor~ be selected depending on the solid content of the solid-liquid mixture to be processed.
Since the centrifuge or the separator according to the present invention is of a doubly-canted decanter configuration, the distance between the free liquid surface of the mixture flowing through the bowl 2 and the inner wall surface of the bowl 2 is large. Therefore, the length of the fins which is inserted in the mixture C~ ~9 in the bowl 2 i8 large for increased separation accuracy and capacity.
The angle by which the fins are inclined to the central axis of the bowl 2, i.e., the screw conveyor shaft, should preferably be small for reduced sedimenta-tion distance and increased separation efficiency. If the angle were too small, however, the gaps between the fins would be clogged by solid particles, and solid particle6 would not be discharged from between the fins.
The angle should preferably be in the range of from 30 to 85 degrees. The surface of the fins may be smooth or may have smooth radial grooves and ridges for an increased surface area that contributes to greater separation capability.
The fins for another embodiment may be in the form of a group of thin plates mounted on the screw conveyor shaft parallel thereto and extending radially outwardly from the screw conveyor shaft obliquely to the free surface of the mixture in the bowl 2 while it is rotating, and the screw conveyor vane may be wound on the outer edges of the thin plates.
The centrifugal forces applied to the mixture in which the fins 7 are inserted are rela~ively small.
Since, however, the distance between the fins 7 and also between the fins 7 and the screw conveyor vane, i~e., the sedimentation distance, i8 small, the sedimentation or swimming and subsequent coalescence of heavy and light particles in the mixture, such as precipitating particles and floating particles shown in Fig. 2, are promoted, resulting in increased separation accuracy. Particular-ly, if the mixture comprises solids and heavy and light liquids, then the heavy and light liquids can be separat:
ed with higher separation accuracy forming boundary surface as shown in Fig. 2, because of coalescence brought about by contact with the fins 7.
The light liquid which has been separated and has passed through the bowl 2 overflows a bank 8 and i8 discharged through an outlet passage 9 out of the 6epara-tox. Likewise, the heavy liquid which ha~ been separated and has passed through the bowl 2 overflows a bank lO and is discharged through an outlet passage 11 of the separa-tor. Thus, the banks 8, 10 ~erve to control the over-flows of the light and heavy liquids.
FIG. 2 shows at enlarged scale the vane of the screw conveyor 3 and the fins 7. FIG. 2 also ~hows the manner in which sedimented and swinging particles move between the fins 7.
FIG. 3 shows a screw conveyor 3 and fins 7 ac cording to another embodiment. The vane of the screw conveyor 3 and the fins 7 are inclined at an angle dif-ferent from the angle at which, i.e., in a direction opposite to the direction in which, the screw conveyor ~ `$~
vane and the fins 7 shown in FIG. 2 are inclined.
For another embodiment, it is preferable to arrange fins in the form of a group of thin plates mount-ed on the screw conveyor shaft parallel thereto and extending radially outwardly from the screw conveyor shaft obliquely to the free liquid surface of the mixture in the rotating bowl 2, and a screw conveyor vane is wound on the outer edges of the thin plates.
Now, comparative Examples 1 and 2 in which con ventional decanters were used to separate a feed mixture, and Inventive Example in which the three-phase separator according to the present invention was used to separate a feed mixture will be described below.
Comparative Example 1: ' 1000 l/h of a feed mixture to be separated were produced rom sardines by a screw press in a fish meal plant and passed through a rotalry screen. The feed mixture was composed of 30.8 vol.% of oil, 61.5 vol.% of water, and 7.7 vol.~ of solids. The feed mixture was supplied to a conventional singly-canted three-phase separation decanter having a bowl with an inside diameter of 250 mm. The feed mixture was separated under centrif-ugal forces of 3000 G at 9S C, into a light liquid com-posed of 2.5 vol.~ or less of water, 2.0 vol.% or less of solids, and the remainder of oil, a heavy liquid composed of 98.7 vol.~ of water, 1.3 vol.~ of solids, and 0.83 wt.% of oil, and a cake composed of about 70 wt.~ of water, 3.0 wt.% of oil, and the remainder of solids.
The light liquid was polished by a cone-disk decanter, for sale as fish oil. The heavy liquid was concentrated into a protein concentrate. The cake was dried by a drier.
The water content in the light liquid produced by the conventional three-phase separation decanter was 1.8 vol.% on average, which was a large value. The solids in the light liquid which were sedimented under centrifugal forces were 2.0 vol.%, which was also a large value. The light liquid was not avaialble immediately as a fish oil product. The oil in the heavy liquid was 0.83 wt.~ and the solids in the heavy liquid which were sedi-mented under centrifugal forces were 1.3 vol.~. These values were also large, and the heavy liquid caused blocking of heater pipes when it was concentrated.
The conventional three-phase separation decanter would not be practically usable as a three-phase separa-tor if the feed mixture were processed only once by the three-phase separation decanter. To make the produced light liquid available as a fish oil product, it is necessary to subsequently polish the light liquid with a cone-disk decanter. The produced heavy liquid is respon-sible for causing trouble with heater pipes when it is .
~4~
concentrated.
ComParative ExamPle 2:
3000 l/h of a feed mixture to be separated were produced from sardines by a screw press and passed through a rotary screen. The feed mixture was composed of 15.6 to 31.5 vol.% of oil, 3.2 to 12.1 vol.% of sol-ids, and the remainder of water. The feed mixture was supplied to a conventional doubly-canted three-phase separation decanter having a bowl with an inside diameter of 320 mm and a screw conveyor shaft with no fins. The feed mixture was separated under centrifugal forces of 3000 G at 90 C, into a light liquid compo~ed of 0.15 wt.%
of water, a trace of solids, and the remainder of oil, a healvy liquid composed of 0.1 to 0.26 wt.% of oil, 0.3 ~ol.% of solids, and the remainder of water, and a cake composed of 1.8 wt.% of oil, about 65 wt.% of water, and the remainder of solids.
The light liquid was of such good quality that it could immediately be shipped as a fish oil product.
The heavy liquid and the cake were processed in the same manner as with Comaprative Example 1. The protein con-centrate produced from the heavy liquid did not cause blocking of heater pipes upon concentration, and hence was of better quality than the protein concentrate in 16 ~9~
Comparative Example 1. The cake was dried more quickly t:han the cake in the Comparative Example 1.
Inventive Exam~le:
5100 l/h of the feed mixture used in Comparative Example 2 was supplied to the three-phase separator according to the present invention. The three-phase separator used had a bowl with an inside diameter of 320 mm and a screw conveyor including six fins with distal ends spaced 20 mm from the inner wall surfa~e of the bowl. The fins had a height of 70 mm on the screw con-veyor shaft, were inclined at an angle of 45 as shown in ~IG. 2, and disposed at equally spaced intervals between turns of the screw con~eyor vane which were ~paced 60 mm from each other. The feed mixture was separated under centrifugal forces of 3000 G at 93 C, into a light liquid composed of 0.12 wt.% of water, a trace of solids, and the remainder of oil, a heavy liquid composed of 0.1 to 0.2 wt.% of oil, 0.3 vol.% of solids, and the remainder of water, and a cake composed of 1.8 wt.% of oil, about 65 wt.% of water, and the remainder of solids.
The light liquid was of such good quality that it could immediately be shipped as a fish oil product.
The heavy liquid and the cake were processed in the same manner as with Comparative Example 2. The protein con-centrate produced from the heavy liquid was as good as , 17 ~ 3 r ~
the protein concentrate in Comparative Example 2. The cake was dried more quickly than the cake in the Compara-tive example 2.
The three-phase separator used in Inventive Example had major diemsnions which were essentially the same as those of the doubly-canted three-phase separation decanter used in Comparative Example 2. Because of the fins provided in the screw conveyor, however, the proc-essing capacity of the three-phase separator in Inventive example was 1.7 times that of the doubly-canted three-phase separation decanter in Comparative Exampel 2 (5100 l/h versus 3000 l/h), and the fish oil as the light liquid and a dilute aqueous solution of the protein concentrate as the heavy liquid had higher purity than those of Comparative ~xample 2 (the water in the light liquids 0.12 wt.~ versus O.lS wt.%, and the oil in the heavy liquid: 0.1 to 0.2 wt.% versus 0.1 to 0.26 wt.~).
It was speculated that the presence of the fins 7 would adversely affect the stability of the dynamic interfacial boundary between the light and heavy liquids.
However, the experimental results of Inventive and Com-parative Examples indicated above show that the improved qualities of the separated light and heavy liquids proved the existence of a stable dynamic interfacial boundary between the light and heavy liquids.
Although certain preferred embodiments of the 9~
present invention have been shown and described in de-tail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.
BACKGROUND OF THE INVENTION
Field of the Invention:
The present invention relates to a sedimentation centrifuge for separating a mixture of solid particles and liquids into solid and liquid phases, and more par-ticularly to a sedimentation centrifuge for separating a mixture of solid particles and two liquid phases, i.e., heavy and light liquids, into the solid particles, the heavy liquid, and the light liquid.
Description of the Prior Arts Heretofore/ centrifuge~ or centrifugal separa-tors are used to separate a mixture of solid particles and liguids into aolid and liquid phases, or a mixture of solid particles and heavy and light liquids into the solid particles, the heavy liquid, and the light liqu~d.
Disk decanters (also called cone-disk decanters) which are in general use for centrifugal sedimentation have a number of spaced conical disks in the form of truncated cones. When a feed slurry of solid-liquid mixture with a large solid content is separated by a disk decanter, however, accumulated solid particles in the mixture tend to clog the gaps between the disks, making 2 210 49~ 9~
the disc decanter fail to operate. To prevent such a problem from happening, it is necessary to reduce the ~mount of solid particles contained in the mixture with, for example, a screw decanter, and then separate the mixture into solid and liquid phases with a disk decant-er. However, this practice requires two expensive de-canters connected in series with each other. Further-more, since the mixture has to be processed under inten-sive centrifugal force twice, the energy consumed by the decanters is relatively large and wasteful.
The inventor has proposed a sedimentation cen-trifuge for ~eparating a mixture of solid particles and liquids into solid and liquid phases, and also a sedimen-tation centrifuge for separating a mixture of ~olid particles and two liquid phases, i.e., heavy and light liquids, into the solid particles, the heavy liquid, and the light li~uid, as disclo~ed in Japanese Patent No.
1,007,732 (Japanese Patent laid-Open No. 054961/75) and Japanese Patent Laid-Open No. 152556/87. The proposed sedimentation centrifuges, which may be termed doubly-canted screw decanters, have a frustoconical bowl for discharging sedimented solid particles. The bowl has an inner wall surface that is canted with respect to the central axis of the bowl first at a larger angle and then at a smaller angle along the direction in which the accumulated solids are discharged. The doubly-canted inner wall surface of the bowl allows the solids to travel smoothly to the end of the bowl and also allows liquid to be removed smoothly from the solid particles.
The bowl structure also serves to increase the amount of feed that stays in the centrifuge for an increased period of time. Therefore, the separation accuracy of the centrifuge and the processing capacity of the centrifuge per unit time are increased.
The inventor has found that much re~mains to be improved in terms of the processing capacity, the separa-tion accuracy, and the amount of required energy in the practical application of the centrifuges. More specifi-cally, as described above, the disk decanter often fails to operate becau~e ~edimented ~olidg tend to clog the gap~ between the disks particularly when feed has a large solid content. This trouble can only be avoided by first reducing the ~olid content in the slurry with the screw decanter and then processing the slurry with the disk decanter. Therefore, the two expensive decanters or centrifuges need to be connected in series with each other, resulting in a wasteful consumption of energy as intensive centrifugal forces are required to be applied twice in the decanters. While the doubly canted screw decanters proposed by the inventor can finish the sepa-rating process when the slurry passes through the centri-fuge only once, the actual use of the proposed decanters has indicated that the proposed decanters are not so advantageous as expected over the series-connected ~en-t;rifugal separators and need further improvement with respect to the processing capacity and the energy con-sumption in applications which demand accurate phase separation.
SUMMARY OF THE INVENTION
It is an ob~ect of the present invention to provide a sedimentation centrifuge which is free of failures due to clogging caused by a slurry or mixture with a large solid content, can separate a slurry with high separation accuracy, consumes a relatively reduced amount of energy, and can ~eparate a relatively large amount of feed highly reliably in only a single cycle of application of centrifugal forces.
According to the present invention, there is provided a sedimentation centrifuge comprising a hollow cylindrical body rotatable about its own central axis, supply means for supplying a solid-liquid mixture into the hollow cylindrical ~ody, a first hollow frustoconical section having an inner wall surface inclined at a larger angle to the central axis, the first hollow frustoconical section having a larger-diameter open end contiguously joined to one end of the hollow cylindrical body and a smaller-diameter open end axially opposite to the Z ~ 9 larger-diameter open end, a second hollow frustoconical section having an inner wall surface inclined at a small-er angle to the central axis, the second hollow frusto-conical section having one open end contiguously joined to the smaller-diameter open end of the first hollow frustoconical section and an opposite open end defining a discharge hole, the one open end being positioned at the same level as or below the free liquid surface of the solid-liquid mixture which is of a cylindrical shape in the hollow cylindrical body while the hollow cylindrical body is rotating, a screw conveyor disposed in the hollow cylidnrical body and the first and second hollow frusto-conical sections for transferring sedimented solids separated from the solid-liquid mixture in the hollow cylindrical body through the first and second hollow frustoconical sections to the discharge hole, bank means on an end of the hollow cylindrical body remote from the discharge hole for controlling an overflow of liquids separated from the solid-liquid mixture, discharge means for discharging the overflow of liquids, and at least one fin mounted on the screw conveyor and di~posed in spaces between turns of the vane of the screw conveyor, the fin being inclined with respect to the central axis.
The bank means may comprise a first bank on an end of the hollow cylindrical body remote from the dis-charge hole for controlling an overflow of a heavy liquid 2 ~ 9 separated from the solid-liquid mixture, and a second bank on an end of the hollow cylindrical body remote from the discharge hole, for controlling an overflow of a light liquid separated from the solid-liquid mixture.
The discharge means may discharge the overflows of heavy and light liquids, respectively. For the purpose of discharging liquids, skimming method is also applicable.
The above and other objects, features, and advantages of the present invention will become apparen~
from the following description when taken in conjunction with the accompanying drawing~ which illustrate preferred embodiments of the present invention by way of example.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic longitudinal crosg-sec~ional view of a sedimentation centrifuge according to the present invention;
FIG. 2 is an enlarged fragmentary longitudinal cross-sectional view of fins and a screw conveyor in the sedimentation centrifuge shown in FIG. l; and FIG. 3 is an enlarged fragmentary longitudinal cross-sectional view of fins and a screw conveyor accord-ing to another embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFE~RED EMBODIM~NTS
As shown in FIG. 1, the three~phase separator 2~Æ9~99 has a supply pipe 1 which extends a~ially into and is open in a large-diameter cylindrical section of a bowl 2 which comprise~ a hollow cylindrical ~ody. A feed slurry or solid-liquid mixture to be separated, which is typi-cally composed of solids and heavy and light liquids, is fed through the supply pipe 1 and holes 12 into the bowl' 2 while the bowl 2 is rotating at high speed. Solid particles contained in the mixture are displaced radially outwardly toward the inner wall surface of the bowl 2 under centrifugal forces which are generated due to the high-speed rotation of the bowl 2.
The bowl 2 ha~ an open discharge end 4 around the supply pipe 1, the open di~charge end 4 defining a d~cgarge hole. The bowl 2 hou~es a screw conveyor 3 which is dispo8ed concentrically therein and extends axially between opposite ends of the bowl 2. The solid particles sedimented on the inner wall surface of the bowl 2 are transferred toward the discharge hole by the screw conveyor 3 which rotates at a speed different from the speed at which the bowl 2 is rotating. The solid particles are then discharged from the discharge hole through an outlet passage 5 out of the three-phase sepa-rator.
The bowl 2 has a doubly-canted portion disposed partly around one end portion of the screw conveyor 3 which is disposed around the supply pipe ~. The doubly-canted portion includes a first frustoconical sectionwhose inner wall surface is inclined at a larger angle to the central axis of the bowl 2 and which has a larger-diameter open end contiguously ~oined to one end of the cylindrical section of the bowl 2, and a second frusto-conical section which has a larger-diameter open end contiguously joined to a smaller-diameter open end of the first frustoconical section and whose inner wall surface is inclined at a smaller angle to the centr~al axis of the bowl 2. The larger-diameter open end of the second frustoconical section is positioned at the same level as or below the free liquid surface or the free surface of the solid-liquid mixture which i~ o a cylindrical shape formed while the bowl 2 i8 rotating. The opposite open end of the ~econd frustoconical section serves as the discharge end 4.
The second frustoconical section includes a beach 6 di~posed near the discharge end 4 and positioned above the level of the mixture in the bowl 2.
Immediately before the sedimented solid parti-cles reach the discharge end 4, the solid particles pass over the beach 6 where remaining li~uid is substantially removed from the solids.
The three-phase separator also includes a plu-rality of helical fins 7 exten~i~g parallel to and posi-tioned between the turns of the flight (vane) of the screw conveyor 3, the fins 7 being mounted on the screw conveyor shaft. The fins 7 are inclined with respect to the central axis of the bowl 2, i.e., the free liquid surface of the solid-liquid mixture of cylindrical shape in the bowl 2 during high-speed rotation thereof. A sub stantial portion of the mixture supplied to the separ~tor flows along the flight of the screw conveyor 3 and the fins 7, and hence is subjected to resistance due to the friction therewith. Therefore, the mixture tends to flow in a region near the inner wall surfacQ of the bowl 2 around the screw conveyor 3 and the fins 7. Since the region near the inner wall surface of the bowl 2 i8 ~paced remotely from the axi~ about which the screw conveyor 3 and the fin~ 7 rotate, the mixture flowing in the reg~on is sub~ected to large centrifugal forces, and can be separated highly efficiently.
The three-phase ~eparator may have one or more helical fins and up to 20 helical fins. The distance between the radially outer tips of the fins and the inner wall surface of the bowl 2 ranges from 5 mm to 100 mm, and each of the fins has a thickness in the range of from 0.5 mm to 2 mm.
The distance between the fins should be as ~mall as possible to reduce the distance that the particles of the mixture have to traverse, i.e., the sedimentation distance, resulting in an increase in the efficiency of 2~
jeimentation. If the distance between the fins were too small, the gaps betwe~n the fins would tend to be clogged by solid particles, preventing solids from being dis-charged from between the fins. Therefore, the distanvce between the fins should be determined depending on the nature of the solid-liquid mixture to be processed.
If the solid-liquid mixture has a larger solid content, then the distance between the radially outer tips of the fins and the inner wall surface of the bowl 2 should preferably be larger. If the solid-liquid mixture has a smaller solid content, then the distance between the radially outer tips of the fins and the inner wall surface of the bowl 2 should preferably be smaller to give the fins an increased unctional surface area for high separation efficiency.
It is therefore preferable that a plurality of screw conveyors with fins of different radial lengths be available, and one of the available screw conveyor~ be selected depending on the solid content of the solid-liquid mixture to be processed.
Since the centrifuge or the separator according to the present invention is of a doubly-canted decanter configuration, the distance between the free liquid surface of the mixture flowing through the bowl 2 and the inner wall surface of the bowl 2 is large. Therefore, the length of the fins which is inserted in the mixture C~ ~9 in the bowl 2 i8 large for increased separation accuracy and capacity.
The angle by which the fins are inclined to the central axis of the bowl 2, i.e., the screw conveyor shaft, should preferably be small for reduced sedimenta-tion distance and increased separation efficiency. If the angle were too small, however, the gaps between the fins would be clogged by solid particles, and solid particle6 would not be discharged from between the fins.
The angle should preferably be in the range of from 30 to 85 degrees. The surface of the fins may be smooth or may have smooth radial grooves and ridges for an increased surface area that contributes to greater separation capability.
The fins for another embodiment may be in the form of a group of thin plates mounted on the screw conveyor shaft parallel thereto and extending radially outwardly from the screw conveyor shaft obliquely to the free surface of the mixture in the bowl 2 while it is rotating, and the screw conveyor vane may be wound on the outer edges of the thin plates.
The centrifugal forces applied to the mixture in which the fins 7 are inserted are rela~ively small.
Since, however, the distance between the fins 7 and also between the fins 7 and the screw conveyor vane, i~e., the sedimentation distance, i8 small, the sedimentation or swimming and subsequent coalescence of heavy and light particles in the mixture, such as precipitating particles and floating particles shown in Fig. 2, are promoted, resulting in increased separation accuracy. Particular-ly, if the mixture comprises solids and heavy and light liquids, then the heavy and light liquids can be separat:
ed with higher separation accuracy forming boundary surface as shown in Fig. 2, because of coalescence brought about by contact with the fins 7.
The light liquid which has been separated and has passed through the bowl 2 overflows a bank 8 and i8 discharged through an outlet passage 9 out of the 6epara-tox. Likewise, the heavy liquid which ha~ been separated and has passed through the bowl 2 overflows a bank lO and is discharged through an outlet passage 11 of the separa-tor. Thus, the banks 8, 10 ~erve to control the over-flows of the light and heavy liquids.
FIG. 2 shows at enlarged scale the vane of the screw conveyor 3 and the fins 7. FIG. 2 also ~hows the manner in which sedimented and swinging particles move between the fins 7.
FIG. 3 shows a screw conveyor 3 and fins 7 ac cording to another embodiment. The vane of the screw conveyor 3 and the fins 7 are inclined at an angle dif-ferent from the angle at which, i.e., in a direction opposite to the direction in which, the screw conveyor ~ `$~
vane and the fins 7 shown in FIG. 2 are inclined.
For another embodiment, it is preferable to arrange fins in the form of a group of thin plates mount-ed on the screw conveyor shaft parallel thereto and extending radially outwardly from the screw conveyor shaft obliquely to the free liquid surface of the mixture in the rotating bowl 2, and a screw conveyor vane is wound on the outer edges of the thin plates.
Now, comparative Examples 1 and 2 in which con ventional decanters were used to separate a feed mixture, and Inventive Example in which the three-phase separator according to the present invention was used to separate a feed mixture will be described below.
Comparative Example 1: ' 1000 l/h of a feed mixture to be separated were produced rom sardines by a screw press in a fish meal plant and passed through a rotalry screen. The feed mixture was composed of 30.8 vol.% of oil, 61.5 vol.% of water, and 7.7 vol.~ of solids. The feed mixture was supplied to a conventional singly-canted three-phase separation decanter having a bowl with an inside diameter of 250 mm. The feed mixture was separated under centrif-ugal forces of 3000 G at 9S C, into a light liquid com-posed of 2.5 vol.~ or less of water, 2.0 vol.% or less of solids, and the remainder of oil, a heavy liquid composed of 98.7 vol.~ of water, 1.3 vol.~ of solids, and 0.83 wt.% of oil, and a cake composed of about 70 wt.~ of water, 3.0 wt.% of oil, and the remainder of solids.
The light liquid was polished by a cone-disk decanter, for sale as fish oil. The heavy liquid was concentrated into a protein concentrate. The cake was dried by a drier.
The water content in the light liquid produced by the conventional three-phase separation decanter was 1.8 vol.% on average, which was a large value. The solids in the light liquid which were sedimented under centrifugal forces were 2.0 vol.%, which was also a large value. The light liquid was not avaialble immediately as a fish oil product. The oil in the heavy liquid was 0.83 wt.~ and the solids in the heavy liquid which were sedi-mented under centrifugal forces were 1.3 vol.~. These values were also large, and the heavy liquid caused blocking of heater pipes when it was concentrated.
The conventional three-phase separation decanter would not be practically usable as a three-phase separa-tor if the feed mixture were processed only once by the three-phase separation decanter. To make the produced light liquid available as a fish oil product, it is necessary to subsequently polish the light liquid with a cone-disk decanter. The produced heavy liquid is respon-sible for causing trouble with heater pipes when it is .
~4~
concentrated.
ComParative ExamPle 2:
3000 l/h of a feed mixture to be separated were produced from sardines by a screw press and passed through a rotary screen. The feed mixture was composed of 15.6 to 31.5 vol.% of oil, 3.2 to 12.1 vol.% of sol-ids, and the remainder of water. The feed mixture was supplied to a conventional doubly-canted three-phase separation decanter having a bowl with an inside diameter of 320 mm and a screw conveyor shaft with no fins. The feed mixture was separated under centrifugal forces of 3000 G at 90 C, into a light liquid compo~ed of 0.15 wt.%
of water, a trace of solids, and the remainder of oil, a healvy liquid composed of 0.1 to 0.26 wt.% of oil, 0.3 ~ol.% of solids, and the remainder of water, and a cake composed of 1.8 wt.% of oil, about 65 wt.% of water, and the remainder of solids.
The light liquid was of such good quality that it could immediately be shipped as a fish oil product.
The heavy liquid and the cake were processed in the same manner as with Comaprative Example 1. The protein con-centrate produced from the heavy liquid did not cause blocking of heater pipes upon concentration, and hence was of better quality than the protein concentrate in 16 ~9~
Comparative Example 1. The cake was dried more quickly t:han the cake in the Comparative Example 1.
Inventive Exam~le:
5100 l/h of the feed mixture used in Comparative Example 2 was supplied to the three-phase separator according to the present invention. The three-phase separator used had a bowl with an inside diameter of 320 mm and a screw conveyor including six fins with distal ends spaced 20 mm from the inner wall surfa~e of the bowl. The fins had a height of 70 mm on the screw con-veyor shaft, were inclined at an angle of 45 as shown in ~IG. 2, and disposed at equally spaced intervals between turns of the screw con~eyor vane which were ~paced 60 mm from each other. The feed mixture was separated under centrifugal forces of 3000 G at 93 C, into a light liquid composed of 0.12 wt.% of water, a trace of solids, and the remainder of oil, a heavy liquid composed of 0.1 to 0.2 wt.% of oil, 0.3 vol.% of solids, and the remainder of water, and a cake composed of 1.8 wt.% of oil, about 65 wt.% of water, and the remainder of solids.
The light liquid was of such good quality that it could immediately be shipped as a fish oil product.
The heavy liquid and the cake were processed in the same manner as with Comparative Example 2. The protein con-centrate produced from the heavy liquid was as good as , 17 ~ 3 r ~
the protein concentrate in Comparative Example 2. The cake was dried more quickly than the cake in the Compara-tive example 2.
The three-phase separator used in Inventive Example had major diemsnions which were essentially the same as those of the doubly-canted three-phase separation decanter used in Comparative Example 2. Because of the fins provided in the screw conveyor, however, the proc-essing capacity of the three-phase separator in Inventive example was 1.7 times that of the doubly-canted three-phase separation decanter in Comparative Exampel 2 (5100 l/h versus 3000 l/h), and the fish oil as the light liquid and a dilute aqueous solution of the protein concentrate as the heavy liquid had higher purity than those of Comparative ~xample 2 (the water in the light liquids 0.12 wt.~ versus O.lS wt.%, and the oil in the heavy liquid: 0.1 to 0.2 wt.% versus 0.1 to 0.26 wt.~).
It was speculated that the presence of the fins 7 would adversely affect the stability of the dynamic interfacial boundary between the light and heavy liquids.
However, the experimental results of Inventive and Com-parative Examples indicated above show that the improved qualities of the separated light and heavy liquids proved the existence of a stable dynamic interfacial boundary between the light and heavy liquids.
Although certain preferred embodiments of the 9~
present invention have been shown and described in de-tail, it should be understood that various changes and modifications may be made therein without departing from the scope of the appended claims.
Claims (2)
1. A sedimentation centrifuge comprising:
a hollow cylindrical body rotatable about its own centrla axis;
supply means for supplying a solid-liquid mix-ture into said hollow cylindrical body;
a first hollow frustoconical section having an inner wall surface inclined at a larger angle to said central axis, said first hollow frustoconical section having a larger-diameter open end contiguously joined to one end of said hollow cylidnrical body, and a smaller-diameter open end axially opposite to said larger-diameter open end;
a second hollow frustoconical section having an inner wall surface inclined at a smaller angle to said central axis, said second hollow frustoconical setion having one open end contiguously joined to said smaller-diameter open end of the first hollow frustoconical section and an opposite open end defining a discharge hole, said one open end being positioned at the same level as or below the free surface of the solid-liquid mixture which is of a cylindrical shape in said hollow cylindrical body while the hollow cylindrical body is rotating;
a screw conveyor disposed in said hollow cylin-drical body and said first and second hollow frustoconi-cal sections for transferring sedimented solids separated from said solid-liquid mixture in said hollow cylindrical body through said first and second hollow frustoconical sections to said discharge hole;
bank means on an end of said hollow cylindrical body remote from said discharge hole for controlling an overflow of liquids separated from said solid-liquid mixture;
discharge means for discharging said overflow of liquids; and at least one fin mounted on said screw conveyor and disposed in spaces between turns of the vane of said screw conveyor, said fin being inclined with respect to said central axis.
a hollow cylindrical body rotatable about its own centrla axis;
supply means for supplying a solid-liquid mix-ture into said hollow cylindrical body;
a first hollow frustoconical section having an inner wall surface inclined at a larger angle to said central axis, said first hollow frustoconical section having a larger-diameter open end contiguously joined to one end of said hollow cylidnrical body, and a smaller-diameter open end axially opposite to said larger-diameter open end;
a second hollow frustoconical section having an inner wall surface inclined at a smaller angle to said central axis, said second hollow frustoconical setion having one open end contiguously joined to said smaller-diameter open end of the first hollow frustoconical section and an opposite open end defining a discharge hole, said one open end being positioned at the same level as or below the free surface of the solid-liquid mixture which is of a cylindrical shape in said hollow cylindrical body while the hollow cylindrical body is rotating;
a screw conveyor disposed in said hollow cylin-drical body and said first and second hollow frustoconi-cal sections for transferring sedimented solids separated from said solid-liquid mixture in said hollow cylindrical body through said first and second hollow frustoconical sections to said discharge hole;
bank means on an end of said hollow cylindrical body remote from said discharge hole for controlling an overflow of liquids separated from said solid-liquid mixture;
discharge means for discharging said overflow of liquids; and at least one fin mounted on said screw conveyor and disposed in spaces between turns of the vane of said screw conveyor, said fin being inclined with respect to said central axis.
2. A sedimentation centrifuge comprising:
a hollow cylidnrical body rotatable about its own central axis;
supply means for supplying a solid-liquid mix-ture into said hollow cylindrical body;
a first hollow frustoconical section having an inner wall surface inclined at a larger angle to said central axis, said first hollow frustoconical section having a larger-diameter open end contiguously joined to one end of said hollow cylindrical body, and a smaller-diameter open end axially opposite to said larger-diame-ter open end;
a second hollow frustocinical section having an inner wall surface inclined at a smaller angle to said central axis, said second hollow frustoconical section having one open end contiguously joined to said smaller-diameter open end of the first hollow frustoconical section and an opposite open end defining a discharge hole, said one open end being positioned at the same level as or below the free surface of the solid-liquid mixture which is of a cylidnrical shape in said hollow cylidnrical body while the hollow cylindrical body is rotating;
a screw conveyor disposed in said hollow cylin-drical body and said first and second hollow frustoconi-cal sections for transferring sedimented solids separated from said solid-liquid mixture in said hollow cylindrical body through said first and second hollow frustoconical sections to said discharge hole;
a first bank on an end of said hollow cylindri-cal body remote from said discharge hole for controlling an overflow of a heavy liquid separated from said solid-liquid mixture;
a second bank on an end of said hollow cylindri-cal body remote from said discharge hole for controlling an overflow of a light liquid separated from said solid-liquid mixture;
discharge means for discharging said overflows of heavy and light liquids; and at least one fin mounted on said screw conveyor and disposed in spaces between turns of the vane of said screw conveyor, said fin being inclined with respect to said central axis.
a hollow cylidnrical body rotatable about its own central axis;
supply means for supplying a solid-liquid mix-ture into said hollow cylindrical body;
a first hollow frustoconical section having an inner wall surface inclined at a larger angle to said central axis, said first hollow frustoconical section having a larger-diameter open end contiguously joined to one end of said hollow cylindrical body, and a smaller-diameter open end axially opposite to said larger-diame-ter open end;
a second hollow frustocinical section having an inner wall surface inclined at a smaller angle to said central axis, said second hollow frustoconical section having one open end contiguously joined to said smaller-diameter open end of the first hollow frustoconical section and an opposite open end defining a discharge hole, said one open end being positioned at the same level as or below the free surface of the solid-liquid mixture which is of a cylidnrical shape in said hollow cylidnrical body while the hollow cylindrical body is rotating;
a screw conveyor disposed in said hollow cylin-drical body and said first and second hollow frustoconi-cal sections for transferring sedimented solids separated from said solid-liquid mixture in said hollow cylindrical body through said first and second hollow frustoconical sections to said discharge hole;
a first bank on an end of said hollow cylindri-cal body remote from said discharge hole for controlling an overflow of a heavy liquid separated from said solid-liquid mixture;
a second bank on an end of said hollow cylindri-cal body remote from said discharge hole for controlling an overflow of a light liquid separated from said solid-liquid mixture;
discharge means for discharging said overflows of heavy and light liquids; and at least one fin mounted on said screw conveyor and disposed in spaces between turns of the vane of said screw conveyor, said fin being inclined with respect to said central axis.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA 2049199 CA2049199A1 (en) | 1991-08-14 | 1991-08-14 | Sedimentation centrifuge |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA 2049199 CA2049199A1 (en) | 1991-08-14 | 1991-08-14 | Sedimentation centrifuge |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA2049199A1 true CA2049199A1 (en) | 1993-02-15 |
Family
ID=4148184
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA 2049199 Abandoned CA2049199A1 (en) | 1991-08-14 | 1991-08-14 | Sedimentation centrifuge |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA2049199A1 (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108187925A (en) * | 2017-12-29 | 2018-06-22 | 海申机电总厂(象山) | A kind of double tapered angle rotary drum |
-
1991
- 1991-08-14 CA CA 2049199 patent/CA2049199A1/en not_active Abandoned
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108187925A (en) * | 2017-12-29 | 2018-06-22 | 海申机电总厂(象山) | A kind of double tapered angle rotary drum |
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