JP6217416B2 - Solid-liquid separator - Google Patents

Description

  The present invention relates to a solid-liquid separation device for separating solid particles contained in a liquid, and more particularly, to a solid-liquid separation device effective for separation of solid particles that have no density difference from a liquid or are small. Is.

  When cells, algae, and other microorganisms are cultured to produce pharmaceuticals, fuels, and other useful substances, the cells and microorganisms that are cultured in water (culture A pre-treatment that separates from the liquid) is required.

  Further, as a method for performing desalination treatment of seawater desalination treatment or shale gas accompanying water, there are a reverse osmosis membrane method and a forward osmosis membrane method. When carrying out such a reverse osmosis membrane method or forward osmosis membrane method, it is possible to separate and remove solid particles such as sand, clay and colloid contained in water as a pretreatment before the membrane treatment. Desired. Furthermore, in the case of desalination treatment such as seawater desalination or shale gas accompanying water, solid particles such as algae and other microorganisms, carcasses and metabolites contained in the water are also separated by pretreatment. It is desirable to remove it.

  Furthermore, for the purpose of purifying lakes and marshes, microorganisms such as algae are separated from water.

  When solid-liquid separation is performed, a solid-liquid separation technique using a density difference between solid particles to be separated and a liquid serving as a dispersion medium is widely and generally performed. That is, when the density of solid particles is larger than the density of liquid, sedimentation separation is performed. On the other hand, when the density of the solid particles is smaller than the density of the liquid, levitation separation is performed. Further, when the density difference between the solid particles and the liquid is relatively small, centrifugal separation that promotes sedimentation and floating of the solid particles based on the same solid-liquid density difference as described above by using centrifugal force is performed. Widely done.

  However, cultured cells and microorganisms, and sand, clay, colloids, algae and other microorganisms contained in water, and their dead bodies and metabolites have a small particle size, and are also a dispersion medium. There is a case where there is no difference in density from the culture solution or water or the particles have a small density difference.

  For this reason, it is difficult to separate such solid particles from a liquid by a conventional general solid-liquid separation method using solid-liquid density differences such as sedimentation separation, flotation separation, and centrifugation. Hereinafter, in this specification, the solid particles having a small density difference from the liquid are solids in which the density of the solid particles and the density of the liquid are different from each other by a density that makes solid-liquid separation difficult by normal centrifugation. It means a particle.

  By the way, it is known that Suffman lift acts on solid particles present in a liquid flow having a shear rate gradient regardless of the density difference between the solid particles and the liquid.

  In addition, a method for separating particles in a liquid on the basis of a certain separated particle diameter using Suffman lift has been proposed. This is because when a liquid permeation flow is formed in a permeable membrane, a liquid flow having a shear rate gradient in a direction along the membrane surface is generated on the upstream surface side of the membrane, and the separation particle size is reduced. The Suffman lift (shear lift) acting on the particles having a particle size corresponding to is equal to the permeate flow velocity of the membrane. According to such a method, particles having a particle size equal to or larger than the separation particle size are held on the upstream surface side of the membrane by the action of the Suffman lift, and thus have a particle size smaller than the separation particle size permeating the membrane. It is said that it can be separated from particles (see, for example, Patent Document 1).

  However, the technique disclosed in Patent Document 1 is merely a technique for separating particles in a liquid according to the particle size, and a solid-liquid separation process is performed on solid particles that have no density difference from the liquid or are small. Not something to do.

  Furthermore, Patent Document 1 does not show any countermeasure against fouling (clogging) of a permeable membrane.

JP-T-2001-503669

  Therefore, the present invention can stably carry out a solid-liquid separation process for separating solid particles having no density difference from the liquid or small solids from the liquid over a long period of time while preventing fouling of the membrane. An object of the present invention is to provide a solid-liquid separator.

The present invention, in order to solve the above problems, in correspondence to claim 1, the fixed cylindrical wall with a porous filter medium to and the peripheral wall extending upward downward, and arranged concentrically to the outer periphery of the fixed cylindrical wall A rotating cylindrical wall, a rotating container provided with an end wall that closes a lower end portion of the rotating cylindrical wall, the fixed cylindrical wall, an annular liquid filling space formed between the rotating cylindrical walls, and the liquid A stock solution inlet provided on one end side in the axial direction of the filling space and supplying a stock solution having a small particle size or no solid-liquid density difference from the liquid or containing the particles, and the liquid filling space A particle concentrate outlet provided near the outer periphery on the other end side in the axial direction, a clarified liquid recovery pipe having an upstream end connected to the inside of the fixed cylindrical wall, and an internal pressure inside and outside the fixed cylindrical wall Differential pressure generation to generate a differential pressure that is lower than the pressure in the outer liquid filling space And a rotation driving device for rotating the rotating container, and by rotating the rotating cylindrical wall of the rotating container, the stock solution in the liquid filling space has a flow velocity from the inner peripheral side toward the outer peripheral side. forming a circumferential direction of the flow field with a shear velocity gradient gradually increasing, the particles contained in the stock solution, recovered from the particle concentrate outlet are concentrated near the outer periphery by Safuman lift acting in the flow field The clarified liquid from which the particles are clarified from the stock solution is collected inside the fixed cylindrical wall, and further for detecting the state of fouling in the porous filter medium of the fixed cylindrical wall. A solid-liquid separator having a configuration including a fouling detection unit and a control unit that controls the reversal of the rotary container by the rotation drive unit based on an input from the fouling detection unit To.

Also, in response to claim 2, in the configuration of claim 1, wherein the fouling detecting means for detecting fouling of the porous filter medium of the fixed cylindrical wall, of the stationary cylindrical wall outer and inner and differential pressure gauge that measures the differential pressure, the control device, when the measurement result of the differential pressure input from the differential pressure gauge is increased to a certain set value that is set in advance, the rotating container relative to the rotary drive device It is set as the structure which gives the instruction | command which reverses the rotation direction.

According to the present invention, the following excellent effects are exhibited.
(1) In the solid-liquid separation device of the present invention, even if the particle has a small particle size and does not have a solid-liquid density difference from the liquid of the dispersion medium or is a small particle, the stock solution containing the particle is continuously solidified. By performing a liquid separation treatment, a particle concentrate containing the concentrated particles and a clarified liquid that has been clarified with respect to the particles can be separated and recovered. Therefore, the solid-liquid separation device of the present invention includes cultured cells, microorganisms, etc., and solid particles such as sand, clay, colloids, algae and other microorganisms contained in water, and dead bodies and metabolites thereof. A solid-liquid separation process for separating the liquid from a liquid such as a culture solution or water can be performed.
(2) In addition, solid-liquid separator of the present invention, the the fouling of the porous filter media fixed cylindrical wall progresses, reverse the direction of the circumferential direction of the flow field having a shear velocity gradient of generating in liquid-filled space By doing so, the fouling can be removed (washed), so that the solid-liquid separation process can be carried out stably over a long period of time.

It is a general | schematic cutting side view which shows one Embodiment of the solid-liquid separation apparatus of this invention. It is an AA direction arrow line view of FIG. It is a general | schematic cutting side view which shows the other form of implementation of this invention. It is a general | schematic cutaway side view which shows other form of implementation of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  1 and 2 show an embodiment of the solid-liquid separation device of the present invention.

  That is, the solid-liquid separation device of the present invention is indicated by reference numeral 1 in FIGS. 1 and 2, and includes a fixed cylindrical wall 2 having a cylindrical shape extending in the vertical direction. The fixed cylindrical wall 2 allows a clarified liquid 5 separated from a stock solution 3 containing particles (solid particles) 4 described later through a porous filter medium provided on the peripheral wall to permeate in and out of the peripheral wall. is there. For convenience of illustration, the size of the particles 4 is shown enlarged in FIGS. 1 and 2 (the same applies to FIG. 3 described later).

  When the porous filter medium is a material having strength and rigidity that can maintain the shape of the fixed cylindrical wall 2, the entire fixed cylindrical wall 2 may be made of a porous filter medium. On the other hand, when the porous filter medium is a filtration membrane (filter) that does not have strength and rigidity that can maintain the shape of the fixed cylindrical wall 2, the fixed cylindrical wall 2 is not illustrated, What is necessary is just to set it as the structure formed by attaching the filtration membrane as the said porous filter medium to the opening part of the flame | frame which has openings, such as the grid | lattice form for hold | maintaining the shape (outer shape) of a surrounding wall. The pore size of the porous filter medium (including the filtration membrane) provided in the fixed cylindrical wall 2 depends on the particle size of the particles 4 contained in the stock solution 3 and desired to be separated from the clarified solution 5. In addition, it should be appropriately selected so that the same filtration treatment as that of an ultrafiltration membrane, a nanofiltration membrane, or the like can be performed.

  The outer side of the fixed cylindrical wall 2 includes a cylindrical cylindrical wall 7 having an inner diameter larger than the outer diameter of the fixed cylindrical wall 2, and an end wall 8 that closes the lower end side of the cylindrical wall 7, and The cylindrical wall (hereinafter referred to as a rotating cylindrical wall) 7 of the rotating container 6 that can rotate around a drive shaft 9 attached to the center of the end wall 8 is disposed concentrically. Thereby, an annular liquid filling space 10 extending in the axial direction, that is, the vertical direction is formed between the outer peripheral surface of the fixed cylindrical wall 2 and the inner peripheral surface of the rotating cylindrical wall 7. In addition, the lower end of the fixed cylindrical wall 2 can be arranged close to the inner surface of the end wall 8 of the rotating container 6, so that the gap with the end wall 8 can be reduced. Thereby, the distribution | circulation of the liquid of the inner / outer direction of the fixed cylindrical wall 2 which passed through the clearance gap can be suppressed.

  The drive shaft 9 of the rotary container 6 is connected to a rotary drive device 11 capable of bidirectional rotation. As a result, when the rotary drive device 11 is operated and the rotary container 6 is driven to rotate in one direction or the other in the circumferential direction integrally with the drive shaft 9, the rotary cylindrical wall 7 is formed in the liquid filling space 10. However, it is set as the structure which carries out relative movement continuously to one direction or the other direction of the said circumferential direction with respect to the fixed cylindrical wall 2 which opposes.

  For this reason, when the rotating cylindrical wall 7 is rotated in the clockwise direction shown in FIG. 2 by the arrow r1 in a state where the liquid filling space 10 is filled with the liquid, The liquid is accompanied and moves in the direction of the arrow r1. As a result, as shown schematically in FIG. 2, the liquid in the liquid filling space 10 gradually has a flow velocity from the fixed cylindrical wall 2 side to the rotating cylindrical wall 7 side, that is, from the inner peripheral side to the outer peripheral side. A flow field in the clockwise direction in the plan view (in the direction of the arrow r1) having an increasing shear rate gradient g1 is formed over the entire circumferential direction.

  Similarly, when the rotating cylindrical wall 7 is rotated in the counterclockwise direction in a plan view as indicated by a two-dot chain line arrow r2 in FIG. 2 while the liquid filling space 10 is filled with liquid, the rotation The liquid in the vicinity of the cylindrical wall 7 is accompanied and moves in the direction of the arrow r2. Thereby, the liquid in the liquid filling space 10 is directed from the fixed cylindrical wall 2 side to the rotating cylindrical wall 7 side, that is, from the inner peripheral side to the outer peripheral side, as schematically shown by a two-dot chain line in FIG. Thus, a flow field in the counterclockwise direction in the plan view (in the direction of the arrow r2) having a shear rate gradient g2 in which the flow rate gradually increases is formed over the entire circumferential direction.

  Therefore, in the solid-liquid separation device 1 of the present invention, even if the rotating cylindrical wall 7 of the rotating vessel 6 is rotated in any of the arrow r1 direction and the arrow r2 direction, A circumferential flow field having a shear rate gradient g1 or g2 in which the flow velocity gradually increases from the inner peripheral side toward the outer peripheral side is formed in the liquid stored in the liquid. For this reason, in the liquid filling space 10, even if the rotating cylindrical wall 7 is rotated in either the direction of the arrow r1 or the direction of the arrow r2, all the particles 4 dispersed in the liquid are In the circumferential liquid flow field having the shear velocity gradient g1 or g2, the Suffman lift in the direction from the inner circumference side to the outer circumference side of the liquid filling space 10 is as shown by the arrow f in FIG. It is supposed to work. Therefore, the particles 4 contained in the liquid stored in the liquid filling space 10 are concentrated in the outer peripheral direction in the liquid filling space 10 by the action of the Suffman lift.

  As shown in FIG. 1, the lower end portion, which is one end portion in the axial direction of the liquid filling space 10, has a stock solution inlet 12 a at the downstream end of the stock solution supply pipe 12 piped through the inside of the fixed cylindrical wall 2. And open through the fixed cylindrical wall 2. The upstream end of the stock solution supply pipe 12 is connected to a stock solution supply unit (not shown) for supplying the stock solution 3 in a state where the particles 4 are dispersed in a liquid serving as a dispersion medium. Thereby, in the liquid filling space 10, the stock solution 3 guided through the stock solution supply pipe 12 from the stock solution supply unit (not shown) is continuously supplied from the stock solution inlet 12a.

  A cylindrical channel partition wall 13 having a diameter larger than that of the fixed cylindrical wall 2 and smaller than that of the rotating cylindrical wall 7 is concentric on the upper end side that is the other axial end of the liquid filling space 10. Arranged in a shape. The upper end of the flow path partition wall 13 is arranged at a height position that is substantially the same as the upper end of the rotating cylindrical wall 7 and is aligned with the upper end of the fixed cylindrical wall 2. Further, the upper end portion of the flow path partition wall 13 is airtightly closed by the closing plate 14. An upper end portion of the fixed cylindrical wall 2 is attached to the lower surface of the closing plate 14.

  Thus, the upper end portion of the liquid filling space 10 is partitioned by the flow path partition wall 13 toward the inner periphery (closer to the fixed cylindrical wall 2) and the outer periphery (closer to the rotating cylindrical wall 7). Among these, a portion near the outer periphery of the upper end portion of the liquid filling space 10 between the flow path partition wall 13 and the upper end portion of the rotating cylindrical wall 7 is connected to the particle concentrate outlet 15 communicating with the outside of the rotating container 6. It has become. Therefore, as described above, the particles 4 concentrated in the outer peripheral direction by the action of the Suffman lift in the liquid filling space 10 are taken out from the particle concentrate outlet 15 as a particle concentrate 16 together with a part of the liquid. .

  In addition, when the rotary container 6 is driven to rotate, a centrifugal force acts on the liquid that generates a flow field in the circumferential direction in the liquid filling space 10 as described above, and thus the liquid level of the liquid in the liquid filling space 10 is applied. Is inclined to be higher on the outer peripheral side than on the inner peripheral side. At this time, since the liquid overflows the amount exceeding the upper end of the rotating cylindrical wall 7, the outer peripheral end of the liquid surface is at a height position coinciding with the upper end of the rotating cylindrical wall 7. It will be lower. In view of this point, the position of the lower end of the flow path partition wall 13 is also in a state where a liquid level gradient is generated in the liquid in the liquid filling space 10 due to the influence of centrifugal force when the rotary container 6 is rotationally driven. It is assumed that the lower end portion of the flow path partition wall 13 is set so as to be surely immersed under the liquid level. In FIG. 1, for convenience of illustration, the liquid level in the liquid filling space 10 is shown in a horizontal state.

  The undiluted solution supply pipe 12 is attached to the closing plate 14 in the vertical direction. Further, an upstream end of a clarified liquid collection pipe 17 for extracting and collecting the clarified liquid 5 from the inside of the fixed cylindrical wall 2 is attached to the closing plate 14 in the vertical direction. The attachment part of the undiluted solution supply pipe 12 and the clarified liquid collection pipe 17 in the closing plate 14 is kept airtight.

  The clarified liquid recovery pipe 17 is a differential for generating a differential pressure inside and outside the fixed cylindrical wall 2 so that the pressure inside the fixed cylindrical wall 2 is lower than the pressure in the liquid filling space 10 outside. A pump 18 is provided as pressure generating means.

  In operation, the pump 18 sucks the liquid inside the fixed cylindrical wall 2 into the clarified liquid recovery pipe 17 to generate the differential pressure inside and outside the fixed cylindrical wall 2. Based on this differential pressure, the liquid located near the inner periphery (closer to the fixed cylindrical wall 2) in the liquid filling space 10 is taken out through the porous filter medium on the peripheral wall of the fixed cylindrical wall 2. is there. At this time, as described above, in the liquid filling space 10, the particles 4 contained in the stock solution 3 are concentrated in the outer peripheral direction by the action of the Suffman lift, and therefore, from the inner periphery of the liquid filling space 10. The liquid taken out to the inside of the fixed cylindrical wall 2 has a relatively reduced concentration of the particles 4. Further, the liquid is subjected to a filtration process when passing through the porous filter medium of the fixed cylindrical wall 2, thereby becoming a clarified liquid 5 in which the concentration of the particles 4 is further reduced.

  The clarified liquid 5 taken out to the inside of the fixed cylindrical wall 2 is then sucked into the clarified liquid recovery tube 17.

  Therefore, the liquid suction amount from the clarified liquid recovery pipe 17 by the operation of the pump 18 is smaller than the supply quantity of the stock solution 3 continuously supplied to the lower end portion of the liquid filling space 10 through the stock solution supply pipe 12. Set as follows. Thereby, excess liquid that is not taken out from the liquid filling space 10 through the porous filter medium of the fixed cylindrical wall 2 to the inside of the fixed cylindrical wall 2 is, as the particle concentrated liquid 16, from the particle concentrated liquid outlet 15. It overflows to the outer peripheral side of the upper end of the rotating cylindrical wall 7.

  The blocking plate 14 to which the flow path partition wall 13 and the fixed cylindrical wall 2 are attached is supported by an external fixed container 19 described later via a support material (not shown) or by a support structure (not shown). The position is fixed. As a result, the fixed cylindrical wall 2, the flow path partition wall 13, and the closing plate 14 are configured to be able to hold their relative positions with respect to the rotating container 6 in a state where there is no possibility of interfering with the rotation of the rotating container 6. Yes.

  Outside the rotating container 6, an external fixed container 19 is provided to cover the lower and outer periphery of the rotating container 6. The particle concentrate 16 overflowing from the upper end of the rotating cylindrical wall 7 may be blown to the outer peripheral side by the action of centrifugal force accompanying the rotation of the rotating container 6. Therefore, the height of the upper end of the external fixed container 19 is set to be equal to or higher than the height position of the upper end of the rotating cylindrical wall 7 of the rotating container 6. Thereby, the particle concentrate 16 that overflows from the particle concentrate outlet 15 to the outer peripheral side of the upper end of the rotating cylindrical wall 7 is received inside the external fixed container 19.

  The bottom of the external fixed container 19 is provided with an opening 20 for allowing the drive shaft 9 to pass through in the center, and the periphery of the opening 20 is from the inner bottom surface of the external fixed container 19 or The particle concentration liquid 16 is stored in the inner bottom portion as a shape that is raised. Further, the external fixed container 19 is provided with a particle concentrate recovery port 21 for recovering the particle concentrate 16 at a certain position on the bottom. In addition, you may provide the inclined surface which inclines below toward the said particle | grain concentrated liquid collection | recovery port 21 in the inner bottom face of the said external fixed container 19 over the whole. Thus, as described above, the particle concentrate 16 received inside the external fixed container 19 is collected at the inner bottom portion of the external fixed container 19 and can be recovered from the particle concentrate recovery port 21.

  Furthermore, the solid-liquid separation device 1 of the present invention is, for example, as a fouling detection means for detecting a fouling state in the porous filter medium of the fixed cylindrical wall 2 that performs a filtration process for generating the clarified liquid 5. A differential pressure gauge 22 for measuring a differential pressure between the upstream side and the downstream side in the liquid passing direction of the porous filter medium is provided. The differential pressure gauge 22 is arranged on the upper side of the blocking plate 14 and is disposed inside the fixed cylindrical wall 2 on the liquid filling space 10 on the upstream side in the liquid passage direction of the porous filter medium and on the downstream side in the liquid passage direction. Are connected to each other via pipe lines.

  The solid-liquid separation device 1 of the present invention further controls the reversal operation of the rotation drive device 11 of the rotary container 6 based on the measurement result of the differential pressure input from the differential pressure gauge 22 as the fouling detection means. The control device 23 is provided.

  Next, the content of the solid-liquid separation process performed using the solid-liquid separation apparatus 1 of the present invention having the above configuration will be described, and the function of the control device 23 will be described.

  When solid-liquid separation processing is performed using the solid-liquid separation device 1 of the present invention, a liquid, for example, the above-mentioned stock solution is previously placed inside the rotary container 6, that is, inside the liquid filling space 10 and the fixed cylindrical wall 2. 3, the liquid serving as the dispersion medium for the particles 4 is stored to a level that coincides with the upper end of the rotating cylindrical wall 7.

  In this state, the rotational driving device 11 starts rotational driving in one circumferential direction of the rotating container 6, for example, in the direction of the arrow r1 in FIG. As a result, a flow field having a shear rate gradient g1 in the inner and outer peripheral directions is formed in the liquid in the liquid filling space 10 over the entire circumferential direction.

  Thereafter, the stock solution 3 guided through the stock solution supply pipe 12 is continuously supplied to the liquid filling space 10 from the stock solution inlet 12 a to the lower end portion of the liquid filling space 10. Further, in the clarified liquid recovery pipe 17, continuous suction of the liquid inside the fixed cylindrical wall 2 is started by starting the operation of the pump 18.

  Thereby, in the liquid filling space 10, the stock solution 3 supplied to the lower end of the liquid filling space 10 is moved from the lower end side (one axial direction end side) to the upper end side (axial center other end side). To the inner and outer peripheral directions in a state where a circumferential flow field having a shear rate gradient g1 is generated. At this time, even if the particle 4 contained in the stock solution 3 has a small particle size, even if there is no density difference from the liquid serving as the dispersion medium or the density difference is small. By the Suffman lift directed toward the outer circumferential direction (arrow f direction), which is a fluid force acting on the particles 4 in the flow field having the shear velocity gradient g1, it is gradually concentrated near the outer circumference close to the rotating cylindrical wall 7. .

  The particles 4 concentrated near the outer periphery in the liquid filling space 10 become a particle concentrated liquid 16 together with a part of the liquid, and the particle concentration provided on the outer periphery of the upper end of the liquid filling space 10. The liquid outlet 15 overflows and is received inside the external fixed container 19. Thereafter, the particle concentrate 16 is collected in the external fixed container 19 and recovered from the particle concentrate recovery port 21.

  On the other hand, in the liquid filling space 10, the liquid which has been relatively clarified with respect to the particles 4 as the particles 4 are concentrated in the particle concentrated liquid 16 is contained in the liquid filling space 10. It is located near the fixed cylindrical wall 2 in the periphery. Further, the liquid located near the fixed cylindrical wall 2 in the liquid filling space 10 is porous in the fixed cylindrical wall 2 due to a differential pressure generated inside and outside the fixed cylindrical wall 2 by the operation of the pump 18. When continuously taken out to the inside of the fixed cylindrical wall 2 through the filter medium, the particle 4 is further reduced to a clarified liquid 5 by being filtered by the porous filter medium.

  The clarified liquid 5 taken out to the inside of the fixed cylindrical wall 2 is then recovered through the clarified liquid recovery tube 17.

  The solid-liquid separation process which isolate | separates and collect | recovers the particle | grain concentrated liquid 16 which concentrated the particle | grains 4 contained in the undiluted | stock solution 3 and the clarified liquid 5 which clarified about this particle | grain 4 by the above is performed.

  By the way, in the solid-liquid separation apparatus 1 of the present invention, when the solid-liquid separation process is continuously performed, the porous filter medium of the fixed cylindrical wall 2 that continuously performs the filtration process for producing the clarified liquid 5 is performed. Fouling occurs.

  At this time, in the fixed cylindrical wall 2, as the fouling of the porous filter medium proceeds, the resistance when the liquid passes from the outside to the inside of the fixed cylindrical wall 2 gradually increases. For this reason, the fouling situation in the porous filter medium, that is, the situation where the filtration performance is lowered, is measured by the differential pressure gauge 22 on the outer side (upstream side in the liquid passage direction) and the inner side (liquid passage direction). The differential pressure with respect to the direction downstream side) can be determined as an index.

  In particular, in the filtration membrane generally sold as a product, regarding the reduction in filtration performance due to the progress of fouling of the filtration membrane, regarding the differential pressure between the upstream side and the downstream side of the filtration membrane when performance recovery is required, Manufacturers often publish as one of the characteristics of the filtration membrane.

  Therefore, the control device 23 is used as a criterion for determining when the porous filter medium used in the fixed cylindrical wall 2 is in a state where performance recovery is required due to performance degradation accompanying the progress of fouling. A certain set value (threshold value) can be set in advance for the differential pressure.

  Furthermore, when the measurement result of the differential pressure is input from the differential pressure gauge 22 in a state where a certain set value serving as the determination reference is set in advance, the control device 23 and the differential pressure measurement result A process of comparing with a certain set value is performed. As a result of this comparison, when the measurement result of the differential pressure is less than the certain set value, the control device 23 indicates the rotational direction of the rotary container 6 to the rotary drive device 11 at that time. Gives a command to continue rotation while holding.

  On the other hand, when fouling in the porous filter medium of the fixed cylindrical wall 2 progresses and the performance recovery is required, the control device 23 measures the differential pressure input from the differential pressure gauge 22. Increases to reach the certain set value. In this case, the control device 23 gives a command to the rotation drive device 11 to reverse the rotation direction of the rotating container 6. Further, the control device 23 gives a command to the rotational drive device 11 to increase the rotational speed of the rotating container 6 after reversing the rotational direction to the same rotational speed as before (before reversal).

  As a result, the rotation direction of the rotating container 6 when being rotated by the rotation driving device 11 is reversed from the direction indicated by the arrow r1 to the direction indicated by the arrow r2 in FIG. It is rotationally driven at the same rotational speed as before. For this reason, the stock solution 3 in the liquid-filled space 10 is rotated in the direction of rotation of the stock solution 3 (liquid) having a shear rate gradient g1 as shown in FIG. A flow field in the direction of the arrow r2 of the stock solution 3 (liquid) having a shear velocity gradient g2 as shown by a two-dot chain line in FIG. 2 that has the same magnitude as the velocity gradient g1 and faces in the opposite direction in the circumferential direction is generated.

  Therefore, in the liquid filling space 10, the Suffman lift in the direction indicated by the arrow f in FIG. 2 (the direction from the inner periphery to the outer periphery) is always applied to the particles 4 contained in the stock solution 3, The direction of the flow field in the circumferential direction of the stock solution 3 in the liquid filling space 10 can be reversed.

  Thus, in the liquid filling space 10, the fixed cylindrical wall 2 is obtained by reversing the direction of the flow field in the circumferential direction of the stock solution 3 while concentrating the particles 4 contained in the stock solution 3 toward the outer periphery. The fouling is removed (washed) on the surface of the porous filter medium exposed to the liquid-filled space 10.

  Thus, in the porous filter medium of the fixed cylindrical wall 2 in which the fouling has been washed, the performance of the filtration performance can be recovered. Accordingly, in the differential pressure gauge 22, the value of the measurement result of the differential pressure inside and outside the fixed cylindrical wall 2 decreases.

  In addition, the particulate matter generated in association with the fouling removal process for the porous filter medium of the fixed cylindrical wall 2 is moved closer to the outer periphery in the liquid filling space 10 by the action of the Suffman lift force, and thus in the stock solution 3. The particles 4 can be recovered together with the particle concentrate 16.

  Thereafter, under the condition that the rotation direction of the rotating container 6 is reversed, the control device 23, as described above, the measurement result of the differential pressure input from the differential pressure gauge 22, and the certain setting. When the differential pressure measurement result is less than the certain set value, the rotation direction of the rotary container 6 is maintained while the differential pressure measurement result is the certain set value. Is reached, the rotation drive device 11 is instructed to restore the rotation speed after reversing the rotation direction of the rotary container 6.

  As described above, according to the solid-liquid separation device 1 of the present invention, even if the particle 4 has a small particle diameter, or the particle 4 has no or small solid-liquid density difference from the liquid of the dispersion medium, the particle 4 A solid-liquid separation process is continuously performed on the undiluted solution 3 containing the particles 4 to separate and collect the particle concentrate 16 containing the concentrated particles 4 and the clarified solution 5 clarified with respect to the particles 4. Can do.

  Therefore, the solid-liquid separation device 1 of the present invention includes cultured cells, microorganisms, etc., and solids such as sand, clay, colloids, algae and other microorganisms contained in water, and dead bodies and metabolites thereof. A solid-liquid separation process for separating the particles from a liquid such as a culture solution or water can be performed.

  Further, in the solid-liquid separation device 1 of the present invention, when fouling of the porous filter medium on the fixed cylindrical wall 2 proceeds, the direction of the circumferential flow field having shear rate gradients g1 and g2 generated in the liquid filling space 10 Since the fouling can be removed (washed) by inverting the solid-liquid separation process, the solid-liquid separation process can be performed stably over a long period of time.

  Furthermore, in the liquid filling space 10, the rotating cylindrical wall 7 is continuously moved relative to the fixed cylindrical wall 2 in the circumferential direction so that the stock solution 3 in the liquid filling space 10 has a shear rate gradient. Therefore, the Suffman lift force that acts on the particles 4 in the stock solution 3 can be generated reliably and efficiently. Therefore, the liquid filling space 10 can be set to have a short distance from one axial end side that is the supply side of the stock solution 3 to the other axial end side that is the outlet side of the particle concentrate 16.

  Furthermore, in the solid-liquid separation device 1 of the present invention shown in FIGS. 1 and 2, the direction of the flow field having a shear rate gradient generated in the liquid filling space 10 in order to apply the Suffman lift to the particles 4 of the stock solution 3. And the flow direction by supply and discharge of the stock solution 3 connecting the stock solution inlet 12a side and the particle concentrate solution 15 side of the particle concentrate 16 are respectively in the circumferential direction and the axial direction, and are different at right angles. . For this reason, in the liquid filling space 10, in the flow field having the shear rate gradient without depending on the moving speed in the flow direction (axial direction) due to the supply and discharge of the stock solution 3 in the liquid filling space 10. It becomes possible to set the magnitude of the shear rate gradient. Therefore, the solid-liquid separation device 1 of the present invention has the rotational speed of the rotating container 6 having the rotating cylindrical wall 7, the height dimension (axial dimension in the axial direction) of the rotating container 6 (rotating cylindrical wall 7), and the stock solution. 3 can be changed independently, so that the degree of freedom of setting these items can be increased when designing the apparatus.

  Furthermore, the solid-liquid separation device 1 of the present invention can be used in order to save the trouble of re-sterilization of instruments after use when separating and collecting the cultured cells and microorganisms from the culture solution. Each component other than the rotation drive device 11 and the control device 23 in the solid-liquid separation device 1 may be made of a disposable material such as a resin.

  Next, FIG. 3 shows an application example of the solid-liquid separation device 1 of the embodiment of FIGS. 1 and 2 as another embodiment of the present invention.

  That is, the solid-liquid separation device of the present embodiment is denoted by reference numeral 1A in FIG. 3, and in the same configuration as the solid-liquid separation device 1 shown in FIGS. Instead of the configuration in which the stock solution inlet 12 a of the stock solution 3 is provided and the particle concentrate solution outlet 15 of the particle concentrate 16 is provided on the upper end side, one axial end (upper end side) of the liquid filling space 10 is connected to the inlet of the stock solution 3. The other end side (lower end side) in the axial direction is the outlet side of the particle concentrate 16.

  In the present embodiment, the rotating container 6 provided with the rotating cylindrical wall 7 and the rotation driving device 11 have the same configuration as that shown in FIGS. 1 and 2.

  A fixed cylindrical wall 2 is concentrically disposed inside the rotating cylindrical wall 7. The fixed cylindrical wall 2 is configured to include a porous filter medium, like the fixed cylindrical wall 2 in the embodiment of FIGS. 1 and 2. Further, the upper end portion of the fixed cylindrical wall 2 is hermetically closed by a closing plate 14a.

  An annular liquid filling space 10 extending in the vertical direction is formed between the outer peripheral surface of the fixed cylindrical wall 2 and the inner peripheral surface of the rotating cylindrical wall 7, as shown in FIGS. is there.

  A stock solution inlet 24 that is an opening between the fixed cylindrical wall 2 and the rotating cylindrical wall 7 is provided at one end portion (upper end portion) in the axial direction of the liquid filling space 10, and above the stock solution inlet 24. The downstream end of the stock solution supply pipe 12 similar to that shown in FIGS. 1 and 2 is disposed. As a result, in the liquid filling space 10, the stock solution 3 guided through the stock solution supply pipe 12 is continuously supplied from the stock solution inlet 24.

  At the other end portion (lower end portion) of the liquid filling space 10 in the axial direction, the upstream end portion of the particle concentrate recovery pipe 25 piped through the inside of the fixed cylindrical wall 2 is located near the outer periphery thereof. An opening is made through the fixed cylindrical wall 2. In the solid-liquid separation device 1 </ b> A of the present embodiment, the opening at the upstream end of the particle concentrate recovery pipe 25 is used as the particle concentrate outlet 26 of the liquid filling space 10. The particle concentrate recovery pipe 25 is connected to a pump (not shown), and the operation of the pump causes the Suffman lift in the liquid filling space 10 as in the embodiment of FIGS. 1 and 2. The particles 4 concentrated in the outer peripheral direction are sucked and collected from the particle concentrate outlet 26 as a particle concentrate 16 together with a part of the liquid.

  When the rotary container 6 is driven to rotate, a centrifugal force acts on the liquid that generates a flow field in the circumferential direction in the liquid filling space 10 as in the embodiment of FIGS. 1 and 2. The liquid level in the filling space 10 is inclined such that the outer peripheral side is higher than the inner peripheral side. At this time, it is assumed that the height position of the upper end of the rotating cylindrical wall 7 is set such that the inclined liquid surface does not overflow beyond the upper end of the rotating cylindrical wall 7. In FIG. 3, for convenience of illustration, the liquid level in the liquid filling space 10 is shown in a horizontal state.

  The particle concentrate recovery tube 25 is attached to the closing plate 14a so as to penetrate in the vertical direction. Further, an upstream end portion of a clarification liquid recovery pipe 17 having a pump 18 similar to that shown in FIGS. 1 and 2 is attached to the closing plate 14a so as to penetrate in the vertical direction. The attachment parts of the particle concentrate recovery pipe 25 and the clarification liquid recovery pipe 17 with respect to the closing plate 14a are kept airtight.

  In addition, as described above, the solid-liquid separation device 1A of the present embodiment is configured to collect the particle concentrate 16 by directly extracting the particle concentrate 16 from the lower end portion of the liquid filling space 10 into the particle concentrate recovery tube 25. Thus, the external fixed container 19 is omitted.

  Other configurations are the same as those shown in FIGS. 1 and 2, and the same components are denoted by the same reference numerals.

  According to the solid-liquid separation device 1A of the present embodiment having the above-described configuration, the internal space of the liquid filling space 10 formed between the rotating cylindrical wall 7 and the fixed cylindrical wall 2 by the rotational drive of the rotary container 6 is reduced. A flow field in the circumferential direction of the stock solution 3 having a shear rate gradient in which the flow velocity gradually increases from the circumferential side toward the outer circumferential side can be formed.

  Further, by controlling the rotation driving device 11 of the rotating container 6 to reverse the rotating direction of the rotating container 6, the circumferential direction of the flow field of the stock solution 3 formed in the liquid filling space 10 is determined. Can be reversed.

  Therefore, also with the solid-liquid separation device 1A of the present embodiment, the solid-liquid separation process can be performed as in the case of the embodiment shown in FIGS. Therefore, the solid-liquid separation device 1A of the present embodiment can obtain the same effects as those of the embodiment shown in FIGS.

  Next, FIG. 4 shows still another embodiment of the present invention. As an application example of the solid-liquid separation apparatus 1A of the embodiment of FIG. 3, a differential pressure is generated inside and outside the fixed cylindrical wall 2. Another example of the differential pressure generating means is shown.

  That is, the solid-liquid separation device of the present embodiment is indicated by reference numeral 1B in FIG. 4, and has the same configuration as the solid-liquid separation device 1A shown in FIG. Instead of the configuration in which the opened stock solution inlet 24 is provided, the upper end side of the liquid filling space 10 is closed, and the stock solution supply pipe 12 is connected to the upper end side of the liquid filling space 10. As a differential pressure generating means, a pump 27 of a type that pumps the stock solution 3 is provided.

  At the upper end side of the liquid filling space 10, a closing plate 14 a that is airtightly attached to the upper end portion of the fixed cylindrical wall 2 is a disk having a diameter slightly smaller than the inner diameter of the rotating cylindrical wall 7, and the closing plate 14 a A non-contact seal (not shown) such as a labyrinth structure is closed between the outer peripheral end and the inner peripheral surface of the rotating cylindrical wall 7. Further, in the solid-liquid separation device 1B of the present embodiment, a non-contact seal (not shown) similar to the above is provided between the lower end of the fixed cylindrical wall 2 and the inner surface of the end wall 8 of the rotary container 6. May be.

  A downstream end portion of the stock solution supply pipe 12 is attached to a portion near the outer periphery of the closing plate 14 a covering the upper end side of the liquid filling space 10 so as to penetrate in the vertical direction so as to open into the liquid filling space 10. . The attachment part of the undiluted solution supply pipe 12 in the closing plate 14a is kept airtight. In the solid-liquid separation device 1B of the present embodiment, the opening to the liquid filling space 10 at the downstream end of the stock solution supply pipe 12 is a stock solution inlet 28.

  In operation, the pump 27 supplies the stock solution 3 pumped through the stock solution supply pipe 12 to the liquid filling space 10 from the stock solution inlet 28. As a result, the pressure in the liquid filling space 10 is increased, so that the pressure inside the fixed cylindrical wall 2 is relatively increased inside and outside the fixed cylindrical wall 2. A differential pressure that is lower than the pressure is generated.

  Further, in the solid-liquid separation device 1B of the present embodiment, the clarified liquid recovery pipe 17 and the particle concentrate recovery pipe 25 are provided with pressure regulating valves 29 and 30, respectively, so that the perforated wall of the fixed cylindrical wall 2 is porous. By adjusting the ratio of the pressure of the clarified liquid 5 taken out inside through the filter medium and the pressure of the particle concentrated liquid 16 taken out from the particle concentrated liquid outlet 26 provided at the lower end of the liquid filling space 10, the fixed The differential pressure inside and outside the cylindrical wall 2 is adjusted, and the amount of the clarified liquid 5 and the particle concentrated liquid 16 can be adjusted.

  Other configurations are the same as those shown in FIG. 3, and the same components are denoted by the same reference numerals.

  According to the solid-liquid separation device 1B of the present embodiment having the above-described configuration, the same effect can be obtained by using it in the same manner as the embodiment shown in FIG.

  In each of the above-described embodiments, the configuration in which the differential pressure gauge 22 is employed as the fouling detection means is shown. However, in the embodiment of FIGS. 1 and 2 and the embodiment of FIG. 3, for example, FIG. As indicated by the alternate long and short dash line, a load signal of the pump 18 provided in the clarified liquid recovery pipe 17 may be input to the control device 23. In this case, the load of the pump 18 that sucks the clarified liquid 5 from the inside of the fixed cylindrical wall 2 as the fouling of the porous filter medium of the fixed cylindrical wall 2 is preset in the control device 23. If it increases to a certain set value, a command to reverse the rotation direction may be given to the rotation driving device 11 of the rotating container 6.

  In view of the fact that the amount of the liquid recovered as the clarified liquid 5 and the particle concentrated liquid 16 fluctuates as the fouling of the porous filter medium on the fixed cylindrical wall 2 proceeds, the clarified liquid recovery pipe The flow rate (recovered amount) of the clarified liquid 5 recovered through 17 and the recovered amount of the particle concentrate 16 may be measured by a flow meter (not shown), and the result may be input to the control device 23. In this case, a certain set value for a decrease in the recovered amount of the clarification liquid 5 and another certain set value for an increase in the recovered amount of the particle concentrate 16 are set in the control device 23 in advance. The control device 23 reduces the amount of the clarified liquid 5 recovered from the inside of the fixed cylindrical wall 2 to the certain set value by fouling of the porous filter medium of the fixed cylindrical wall 2 or the concentration of the particles. When the amount of the liquid 16 increases to another certain set value, a command to reverse the rotation direction may be given to the rotation driving device 11 of the rotating container 6.

  Furthermore, in the embodiment of FIGS. 1 and 2 and the embodiment of FIG. 3, in view of the fact that the liquid filling space 10 is open to the outside, the pressure inside the fixed cylindrical wall 2 is A pressure gauge that measures the differential pressure from the atmospheric pressure may be used.

  In addition, the present invention is not limited to the above-described embodiments. In each embodiment, the cross-sectional area and the axial direction dimension of the liquid filling space 10 are determined according to the desired throughput of the stock solution 3 and the solid-liquid separation efficiency. It may be changed appropriately according to the situation.

  In the embodiment shown in FIG. 1 and FIG. 2, the configuration in which the stock solution inlet 12a of the stock solution supply pipe 12 is provided at one place in the circumferential direction of the liquid filling space 10 is shown. It is good also as a structure. Further, a ring-shaped header pipe that is continuous in the circumferential direction at the lower end of the liquid filling space 10 is provided at the downstream end of the stock solution supply pipe 12, and a stock solution inlet 12a that is continuous in the circumferential direction is provided in the header pipe. It may be.

  In the embodiment of FIG. 3 and the embodiment of FIG. 4, the configuration in which the particle concentrate outlet 26 of the liquid filling space 10 is provided at one place in the circumferential direction of the liquid filling space 10 is shown. The upstream end of the particle concentrate recovery pipe 25 may be branched so that the particle concentrate outlet 26 is disposed at a location. Furthermore, a ring-shaped header pipe that is continuous in the circumferential direction at a position near the outer periphery of the lower end of the liquid filling space 10 is connected to the upstream end of the particle concentrate recovery pipe 25, and is continuous with the header pipe in the circumferential direction. A particle concentrate outlet 26 may be provided.

  In the embodiment of FIG. 4, the configuration in which the stock solution inlet 28 of the stock solution supply pipe 12 is provided at one location in the circumferential direction of the closing plate 14 a is shown, but the stock solution inlet 28 may be arranged at a plurality of locations in the circumferential direction. .

  The stock solution 3 to be subjected to the solid-liquid separation process in the solid-liquid separation devices 1, 1 </ b> A, 1 </ b> B of the present invention has a higher density than the density of the liquid that is the dispersion medium of the particles 4 in the stock solution 3. The particle | grains 4 which have a large density difference to the side may be included. In this case, the particles 4 having a large density difference with respect to the liquid are moved to the outer peripheral side by utilizing centrifugal force in addition to the Suffman lift in the flow field formed in the circumferential direction in the annular liquid filling space 10. It can be recovered by concentrating.

  The solid-liquid separators 1, 1 </ b> A, and 1 </ b> B of the present invention are particles 4 in a stock solution 3 containing arbitrary particles 4 or a dispersion medium other than water as long as the liquid contains particles 4 that require solid-liquid separation. You may apply to the solid-liquid separation process of the undiluted | stock solution 3 which dispersed.

  Of course, various modifications can be made without departing from the scope of the present invention.

1, 1A, 1B Solid-liquid separation device, 2 fixed cylindrical wall, 3 stock solution, 4 particles, 6 rotating container, 7 rotating cylindrical wall, 8 end wall, 9 drive shaft, 10 liquid filling space, 11 rotating drive device, 12 stock solution Supply pipe, 12a stock solution inlet, 15 particle concentrate outlet, 17 clarified liquid recovery tube, 18 pump (differential pressure generating means), 22 differential pressure gauge (fouling detection means), 23 control device, 24 stock solution inlet, 25 particle concentrate Recovery tube, 26 particle concentrate outlet, 27 pump (differential pressure generating means), 28 stock solution inlet

Claims (2)

A fixed cylindrical wall extending in the vertical direction and provided with a porous filter medium on the peripheral wall;
A rotating cylindrical wall concentrically disposed on the outer periphery of the fixed cylindrical wall, and a rotating container provided with an end wall closing the lower end of the rotating cylindrical wall;
An annular liquid filling space formed between the fixed cylindrical wall and the rotating cylindrical wall;
A stock solution inlet provided on one end side in the axial direction of the liquid filling space, for supplying a stock solution having a small particle size or no solid-liquid density difference with the liquid, or containing a small particle,
A particle concentrate outlet provided near the outer periphery on the other end side in the axial direction of the liquid filling space;
A clarified liquid recovery pipe having an upstream end connected to the inside of the fixed cylindrical wall;
Differential pressure generating means for generating a differential pressure in which the inner pressure is lower than the pressure of the outer liquid filling space inside and outside the fixed cylindrical wall;
A rotation driving device for rotating the rotating container,
By rotating the rotating cylindrical wall of the rotating container, a circumferential flow field having a shear rate gradient in which the flow rate gradually increases from the inner peripheral side toward the outer peripheral side is formed in the stock solution in the liquid filling space, the particles contained in the stock solution, are concentrated near the outer periphery by Safuman lift acting in the flow field is recovered from the particle concentrate outlet, clarified liquid clarification of the particles can be achieved from the stock solution, It is configured to be collected inside the fixed cylindrical wall,
Furthermore, fouling detection means for detecting the state of fouling in the porous filter medium of the fixed cylindrical wall,
A solid-liquid separation device comprising: a control device that controls inversion of the rotating container by the rotation driving device based on an input from the fouling detection means. Wherein said fouling detecting means for detecting fouling of the porous filter media of the fixed cylindrical wall, and a differential pressure gauge for measuring the outer and inner differential pressure of the fixed cylindrical wall,
Wherein the control device, the measurement result of the differential pressure input from the differential pressure gauge is, increasing to a certain set value that is set in advance, gives a command to respect the rotation driving device to reverse the rotation direction of the rotating container The solid-liquid separation device according to claim 1, wherein the device is a solid-liquid separation device.

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