FR2707520A1 - Process for filtering a liquid by tangential flow along a membrane and periodic unblocking - Google Patents

Abstract

Process consisting in making a liquid flow tangentially along a porous and permeable membrane which is periodically unblocked by a back flow of a fraction of a liquid or of the permeate through the membrane. It is characterised in that the unblocking operation is performed according to the following stages: - backflow of the permeate by reversal of flow at a flow rate of higher value than that of a reference flow rate for normal filtration, - progressive decrease in the back flow rate, - stabilisation of the said flow rate, - slow return to the reference flow rate in a normal filtration direction, opposite to that of the back flow.

Description

The present invention relates to an improvement made to the methods

  and filtration devices with a

periodic unclogging.

  There is already known a method of filtering a liquid by tangential flow thereof along a porous and permeable membrane, which is periodically unclogged by a discharge flow, of a fraction of liquid or "permeate", discharged through the membrane, after having crossed it, under the effect of a mechanical pressure difference between the upstream tangential flow and said permeate in such a way that the molecules and particles accumulated on the membrane are eliminated by

flow reversal.

  Such a process makes it possible to obtain ultrafiltration or microfiltration, by means of specific membranes, capable of separating constituents of different molecular weights from one another or relative to

a solvent.

  The liquid to be filtered will hereinafter be called the retentate, while the fraction of liquid passing through the membrane under the effect of the mechanical pressure difference is the permeate, which after being discharged through the membrane takes care of the clogging particles for

become the retentate.

  This retentate can be recycled at the inlet of the device. The accumulation of retentate components causes a progressive blockage of the membrane over time. We know that this clogging can be limited by periodically canceling or reversing the pressure difference between

  the upstream flow along the membrane and the permeate.

  This was previously described in the patent application

French N 2 180 446.

  The present invention aims to improve unclogging by repression of the permeate. It has been found that, at the end of an excessively violent delivery period, the permeate pressure drops rapidly and sharply, causing immediate re-clogging of the membrane. On the other hand, if the return to normal filtration pressure of the permeate compartment is too rapid, the pressure of the permeate drops below its normal operating value and can cause partial vaporization of the permeate and the formation of bubbles which can clog up. the membrane. To this end, the invention relates to a method of

  filtration of a liquid by tangential flow thereof

  ci along a porous and permeable membrane, which is periodically unclogged by a delivery rate, a fraction of a liquid or "permeate", discharged through the membrane, after having crossed it, under the effect of a mechanical pressure difference between the upstream tangential flow and said permeate so that the molecules and particles accumulated on the membrane are eliminated by reverse flow, characterized in that the unclogging operation is carried out according to the following phases: - delivery of the permeate by reversing the flow at a flow rate of value greater than that of a normal filtration reference flow rate, - progressive reduction of the flow rate flow, stabilization of said flow rate, - slow return to the reference flow rate in a sense of

  normal filtration, opposite to that of the discharge.

  It has been determined that the evolution of the discharge flow during unclogging must never cause a violent drop in the permeate pressure which can lead to a sudden reversal of the direction of

  filtration or vaporization of the permeate.

  The progressive deceleration phase lengthens the duration of unclogging or slightly decreases the average delivery rate, which is therefore in the opposite direction to the delivery rate.

normal permeate.

  One would therefore think that the overall yield of the filtration process would be affected. Unexpectedly, we notice on the contrary that the cleaning efficiency is better and that thus the overall yield

is much improved.

  This translates in practice into a medium increase in the volume of permeate filtered, which can

exceed 50%.

  The implementation of the device according to the invention is carried out by various devices capable of controlling the evolution of the permeate delivery rate and that of the pressure of the permeate compartment during unclogging. Thus a first device uses as a pressurizing member a pump whose delivery pressure is controlled by a regulating member, by

example a valve.

  The high permeate delivery rate, its gradual deceleration and its return to the normal operating value are obtained by the programmed operation of the two valves in parallel on the permeate circuit. According to a variant, the device comprises a piston and a cylinder with variable capacity, the pressurization of which is ensured by a reserve of compressed air. The permeate delivery rate is created by the opening of a shut-off valve connecting the reserve of compressed air to the "air" compartment of the device, its gradual slowing down and ensured by the gradual venting of said compartment and the return to normal operating value is ensured by resuming filtration. According to another variant, the device comprises a piston decolmator driven by a motor with controllable and programmable stroke. The piston stroke can thus respect a precise shape ensuring the evolution of the flow of

  repression of the permeate according to the invention.

  The invention will be better understood and other characteristics of it will be highlighted at

  using the following description, with reference to

  schematic appended drawings, illustrating by way of nonlimiting examples how the invention can be implemented and in which: - Figure 1 is a diagram of a filtration installation with permeate delivery pump according to 1 invention; - Figures 2 and 2A are sectional drawings of a decooler with movable piston, according to an alternative embodiment of the invention; - Figure 3 is a diagram of the use of a decolmator according to Figures 2 and 2A suitable for a membrane filtration installation; - Figure 4 is a diagram of a variant of the use of the decooler of Figures 2 and 2A in a

  membrane filtration system.

  According to Figure 1, we see a filter element 1 which comprises a channel 2 for circulation of the liquid solution or retentate between a pressure inlet 3 and an outlet 4 with a pressure drop member 5 for

collect the retentate.

  The pump 7 for pressurizing the system and the pump 8 for sweeping the liquid to be treated are not affected by the invention. A wall of the channel 2 is limited by a filter membrane 6, the collector 9 opens into the permeate circuit A. In normal filtration period, the valve 5 'is closed and the degree of opening of the valve 5 regulates the pressure of the channel 2. The valve 10 is open and the regulating member 11, for example a valve, ensures the overpressure of the permeate circuit A and 9. A part of the permeate is stored in a buffer tank 12 before being evacuated via the line 13 The valve 14 is then closed. The pump 15 runs continuously but its discharge passes through the regulating member 16, and for a pressure greater than the setpoint of the regulating member 16, the discharge of the pump 15 is recycled

to tank 12.

  During unclogging, the discharge valve 5 'opens, thus ensuring a drop in pressure in the retentate. The valve 10 closes, the valve 14 opens. The pressure at the valve 14 drops below the set value of the regulating member 16 and the discharge of the pump 15 ensures the overpressure of the channel 9 and therefore the establishment of the permeate discharge rate. The gradual closing of the valve 14 ensures the

  progressive deceleration of this delivery rate.

  The gradual opening of valve 10 ensures the return to normal operating values and restores the flow of permeate. The control unit 17 controls the valves

and 14.

  According to Figures 2 and 2A, the liquid compartment 18 of the variable capacity cylinder 19 is supplied with permeate through line 20. The line 21 ensures the evacuation of the permeate. The air compartment 22 of the cylinder is connected to a reserve of compressed air (not shown) by means of the conduit 23. The movable piston 24, guided by a segment 25, and provided with seals 26 and 27, transmits the pressure of the compressed air at the permeate compartment 18 of the cylinder. Two bottoms 28 and 29 connected by tie rods 30, 31, 30 'and 31' seal the cylinder 19 by

two flat seals 32 and 33.

  The movable piston 24 supports in its upper part a rod 34 at the hollow end passing through the permeate compartment 18 and sliding freely in the

  pipe 21. The rod 34 acts as a shut-off valve.

  In normal filtration phase, the hollow end of the rod 34 is below the level of the bottom 28 and thus ensures communication between the permeated liquid compartment 18 and the pipe 21 via the pipes 34a

(figure 2).

  In the unclogging phase, the hollow end of the rod 34 is above the level of the bottom 28, preventing

  thus the exit of the permeate via line 21 (FIG. 2A).

  The movable piston 24 supports in its lower part a rod 35 opening into the open air by means of an orifice

  36 drilled in the bottom 29 of the cylinder 19.

  The rod 35 has a possibly hollow end 35a ensuring the gradual venting of the air compartment 22 of the decolmator using a flow regulator 37. The rod 35 is optionally connected to a

displacement sensor 38.

  -_ 6 The return of the piston 24 to its position before unclogging takes place at the rate of resumption of the permeation flow. In Figure 3, we find the membrane system described in Figure 1 and the decolmator described in Figures

2 and 2A.

  In normal filtration phase, the valve 5 ′ is closed and the degree of opening of the valve 5 regulates the pressure of the channel 2. The overpressure of the permeate collector 9 is ensured by the regulating member 39, which

maybe a valve.

  The permeate opens through line 20 into the liquid compartment 18 of the decolmator. It emerges from the hollow end of the rod 34 and is discharged through the

driving 21.

  During this phase, the valve 40 puts the air compartment 22 of the decooler into communication with the open air by means of the flow regulator 41 which is not closed. In the unclogging phase, the discharge valve 5 ′ opens, triggering the opening of the valve 40 which places the compressed air reserve 42 and the air compartment 22 of the unclogging device in communication. The sudden increase in pressure in the compartment 22 displaces the movable piston 24 and closes the permeate outlet 21 using the rod 34. The permeate contained in the liquid compartment 18 is therefore discharged into the line 20, passes through of the valve 43 and passes through the membrane 6 in the opposite direction to the normal filtration. The discharge flow is therefore

established.

  When the displacement sensor 44 has detected that the volume of permeate reinjected corresponding to its setpoint is reached, it triggers the venting

  of compartment 22 by means of the three-way valve 40.

  The venting rate is regulated and controlled - by the flow regulator 41 causing a gradual slowing down of the permeate delivery rate in the

channel 9.

  The discharge valve 5 'closes, triggering an increase in the pressure of the retentate in the channel 2 and thus gradually restoring the normal permeate flow rate which causes the piston 24 to return to its position

before unclogging.

  In accordance with the invention, the high permeate delivery rate is gradually slowed down by the flow regulator 41 and the slow return to normal permeation rate is achieved by progressive restoration.

filtration.

  During the unclogging phase, the pressure of channel 9 is higher than the target pressure of the organ

regulator 39.

  According to a variant illustrated in FIG. 4, the conduct of the unclogging phase may consist of the use of a hollow rod 35. Figure 4 shows

  in fact a variant of the system presented in FIG. 3.

  The normal filtration phase is identical to the

previous system.

  In the unclogging phase, the discharge valve 5 ′ opens, triggering the opening of the valve 46 which places the compressed air reserve 42 and the air compartment 22 of the unclogging device in communication. The sudden increase in pressure in the compartment 22 displaces the movable piston 24 and closes the permeate outlet 21 using the rod 34. The permeate contained in the liquid compartment 18 is therefore discharged into the line 20, passes through of the valve 43 and passes through the membrane 6 in the opposite direction to the normal filtration. The discharge flow is therefore established. When the hole 47 is above the bottom 29, it puts the air compartment 22 of the decolmator into the open air. The progressiveness of this venting is ensured by the flow regulator 37, causing a gradual slowing down of the permeate delivery rate in the

channel 9.

  The discharge valve 5 'closes, triggering an increase in the pressure of the retentate in the channel 2 and thus gradually restoring the permeate flow rate which causes the piston 24 to return to its position before unclogging. In accordance with the invention, the high permeate delivery rate is gradually slowed down by the flow regulator 37 and the slow return to the normal permeation rate is achieved by progressive restoration.

filtration.

  During the unclogging phase, the pressure of channel 9 is higher than the target pressure of the organ

regulator 39.

EXAMPLE

  UHT (Ultra High Temperature) skimmed milk was filtered with a 0.2m2 surface membrane and

average pore diameter of 1.4 m.

  The unclogging was caused every minute,

  either with damped piston or with non-damped piston.

  After approximately 30 minutes of filtration, the permeate flow rates were measured before and after the last unclogging. This operation was started again after changing the milk concentration (volume concentration factor increased from 1 to 3) the results are given in

the table below.

  The average transmembrane pressure was 2 bars,

  the temperature of 30 C, and the scanning speed of 4m / s.

  The two sets of results represent two conditions

  damping different from the discharge flow.

  Concentration factor Filtrate flow rate Filtration flow rate by volume in 1 / bm2 in 1 / hm2 (FCV) damped stroke Normal stroke in accordance with the invention 1,325,440 flow before unclogging 435,545 flow after unclogging 380,492.5 Average 3,155 270 flow before unclogging 225,375 flow after unclogging 322.5 Average 1,180,375 flow before unclogging 300,465 flow after unclogging 240,420 Average 3 50 180 flow before unclogging 240 flow after unclogging 210 Medium It can be seen that the damping of the discharge flow has a favorable effect on the maintenance of permeation rates. The drop in permeability for the last unclogging is lower in the case of unclogging with damping, in particular for

  higher concentrations (FCV = 3 in the table).

Claims (7)

  1) Method of filtering a liquid by tangential flow thereof along a porous and permeable membrane, which is periodically unclogged by a discharge flow, of a fraction of a liquid or "permeate", discharged through the membrane, after having passed through it, under the effect of a mechanical pressure difference between the upstream tangential flow and said permeate in such a way that the molecules and particles accumulated on the membrane are eliminated by reverse flow, characterized in that the unclogging operation is carried out according to the following phases: - delivery of the permeate by flow reversal at a flow rate of value greater than that of a normal filtration reference flow rate, - progressive reduction of the delivery flow rate , stabilization of said flow, - slow return to the reference flow in a direction of   normal filtration, opposite to that of discharge.   2) A filtration device for implementing the method according to claim 1, characterized in that the phases ensuring unclogging by discharge are ensured by two stop valves (10, 14) arranged in parallel on the filtration circuit, one (10) ensuring the protection of a regulating member (11) of the transmembrane pressure in operation without unclogging, the other (14) ensuring the protection of a pumping member (15) operating continuously and which is regulated by a regulating member (16), their valves   (10, 14) being controlled by a control member (17).   3) A filtration device according to claim 2, characterized in that the regulating member (11) is a valve. 4) Device for implementing the method according to claim 1, characterized in that the unclogging by delivery is ensured by a movable piston (24) and a variable capacity cylinder (19) pressurized by an air reserve compressed, the permeate delivery rate   being created by the opening of a stop valve (34).   ) Device according to claim 4, characterized in that the piston (24) has an extension (35)   passing through the bottom (29) of the cylinder (19).   6) Device according to claim 5, characterized in that the extension (35) is provided with a hollow end (35a) having an orifice for venting the cylinder (19).   7) Device according to claim 5 or 6, characterized in that the extension (35) is connected to a displacement sensor (38).   8) Device according to claim 5 or 6, characterized in that the venting of the cylinder (19) is made progressive by means of a flow regulator (37), disposed at the end of the extension (35).   9) Device according to one of claims 4 to 8,   characterized in that the piston (24) is driven by a motor   with controllable and programmable stroke.   10). Device according to one of claims 4 to 9,   characterized in that the regulation of the permeate in normal operation is ensured by a regulating member (39) which is derived during the unclogging phase in   a pipe comprising a valve (43).