FR2674448A1 - Process for cleaning mesoporous tubular ultrafiltration membranes - Google Patents

Abstract

Process for cleaning mesoporous tubular ultrafiltration membranes fitted as a bundle in a housing, with bounding of a concentrate compartment where the retained substances accumulate both in suspension and on the membranes, and of a permeate compartment collecting the filtered liquid, characterised in that it includes the stages consisting in a) emptying the concentrate compartment to remove the liquid to be filtered which it contains and the suspended matter, and then b) carrying out back-washing by passing liquid from the permeate compartment towards the concentrate compartment through the membranes to detach and remove the impurities deposited on the latter. The process applies to all types of mesoporous ultrafiltration membranes with tubular geometry including hollow fibres (symmetrical, asymmetrical, inner-skinned or outer-skinned).

Description

 The invention relates to a method for cleaning mesoporous tubular membranes (including hollow fibers), especially those having average pore diameters substantially less than 0.1 Hm, used for the ultrafiltration of liquids.

 Such tubular membranes are generally used in the form of a filtration module comprising a casing inside which is placed at least one set of tubular membranes, at least one end of the channel existing inside each membrane communicating with the membrane. outside the housing by a suitable device, for example through a head plate. The liquid to be filtered, for example turbid water to be converted into clear water, is admitted into the module inside the membranes or outside the membranes, depending on the direction of filtration through the membrane. with outer skin, the filtration is from the outside to the inside, the impurities accumulate in the inner space of the housing on and around the membranes, forming respectively a filtering vessel on the membranes and a concentrate of materials in suspension around the membranes, in what is called the concentrated compartment. The filtered liquid is discharged through the central channel of each membrane, this central channel constituting the permeate compartment.

 When the thickness of the layer of material deposited on the membrane reaches a limit harmful to a sufficient production of permeate, it is necessary to wash the membranes. A known method is to wash against the current (backwashing) with clean liquid or a gas. The washing product is then injected under pressure in the opposite direction to the direction of the filtration and, by passage through the membranes, off the deposited material by resuspending in the concentrate which is purged during washing through an evacuation device (valve or the like).

 However, it has been found that, to be effective, backwashing requires either a high injection pressure or a duration and consumption of detergent (liquid or gas) and a loss of important concentrates, which affects the performance of the filtration set.

 It has now unexpectedly been found that if backwashing with a washing liquid is carried out after having emptied the concentrated compartment, the efficiency of backwashing is substantially improved in a shorter time and with a lower consumption of washing liquid. concentrate.

There is thus provided a method of cleaning mesoporous ultrafiltration tubular membranes mounted in a housing, with delimitation of a concentrated compartment where the suspended materials accumulate both in suspension and on the membranes on the one hand and a permeate compartment collecting the filtered liquid on the other hand, characterized in that it comprises the steps of:
empty the concentrated compartment to evacuate the liquid to be filtered and the suspended matter that it contains, then
b) carry out a backwash by passage of liquid from the permeate compartment to the compartment concentrate through the membranes to take off and remove the impurities deposited thereon.

 According to a first variant, step a) is carried out by opening an evacuation system of the concentrat compartment and opening an atmospheric pressurizing device of the concentrated compartment.

 According to a second variant, step a) is carried out by opening a device for discharging the concentrated compartment and injecting a gas under pressure into the concentrated compartment.

 According to a third variant, step a) is carried out by suctioning the liquid contained in the concentrated compartment with the aid of a pumping means and by opening a device for putting the concentrat compartment under atmospheric pressure.

 The two steps a) and b? can be performed with without stopping the liquid supply to be treated.

 In a first embodiment, step b) is performed by injecting the washing liquid in overpressure with respect to the air (or gas) pressure prevailing in the concentrated compartment.

 In a second embodiment of step b), the concentrated compartment is placed under partial vacuum.

 Finally, in a third embodiment, step b) is performed by injection of washing liquid under overpressure and partial vacuum of the concentrated compartment (combination of the two previous embodiments).

 Without wishing to be bound to any theory, it is considered that the improvement of the efficiency of the backwashing is due to the following reason: after its emptying the concentrated compartment is full of air or gas injected at atmospheric pressure or under pressure . During backwashing, the washing liquid (eg water) passes through the membranes and flows on the other side and along the membranes forming a liquid film which forms a ring around each membrane rapidly sliding along the membranes. favoring the backwashing of the deposited materials and entrainment of the removed materials. The velocity of the flow of the liquid film is greater than that which one would have if the concentrated compartment were full of water. The total quantity of liquid flowing along the membrane increases in descending, which increases the liquid film thickness and flow rate.

 According to the permeability and the outer diameter of the membranes, there is a limit membrane length beyond which the flow of washing liquid is no longer in the form of liquid films independent of each other and surrounding each membrane, but all liquid films meet, a stream of liquid occupying all the space between the membranes. But there is enough air in the concentrated compartment, consisting here of the inner space between the membranes and between the housing and the membrane bundle or beams so that the liquid stream has a higher speed of movement than it would be if the housing was full of fluid under the same conditions of backwashing.

 An additional advantage of the cleaning method according to the invention is that the emptying of the concentrated compartment before the backwash makes it possible to eliminate almost all if not all suspended or dissolved materials not deposited on the membranes. The amount of backwash liquid is then limited to that required to take off the deposit membranes and to drive towards the outlet of the compartment concentrate.

 The invention is not limited to the case where the concentrated compartment is constituted by the interior space of the housing and wherefore the permeate compartment is constituted by the internal space of the membranes.

 The method also applies to mesoporous tubular membranes with internal skin - for which filtration is carried out from the inside (concentrat compartment) outwards (permeate compartment), tubular membranes, as well as symmetrical tubular membranes. (double skin) or isotropic (without skin) for which it is the direction of filtration that defines the permeate and concentrate compartments, the permeate compartment being constituted by the internal space of the membranes when the filtration is done from outside to the interior of the membranes and the outer space around and between the membranes when the filtration is from the inside to the outside of the membranes, the concentrated compartment being then respectively the other space delimited by the membranes.

 The cleaning method according to the invention finds an application in all cases where filtration is carried out on tubular membranes, regardless of the liquid to be filtered and whatever the nature of the tubular membranes used. It may especially be used on mesoporous tubular membranes with internal skin, outer skin, double skin or isotropic and whatever the chemical nature of the tubular membrane (polymer, ceramic, etc.). It finds a particular application on an industrial scale in the treatment of water for distribution in public networks, using tubular membranes made of a porous polymer. This is the application that will be implemented in the following examples without limiting the invention to this sole use.

 The single figure schematically illustrates the hydraulic circuit in the case of a module of outer skin tubular membranes 2 contained in a housing 1.

 The turbid water supply is done by the feed pump P1 in the housing and the clear water (permeate) is collected in the head 4 of the housing and collected in a permeate tank 5 which can be isolated from the module. ultrafiltration by a V2 valve. A valve 71 at the bottom of the casing 1 and a valve V4 at the head of it allow the emptying of the concentrat compartment 3. The backwashing is done via a pipe 6 recycling a portion of the permeate of the tank 5 to the permeate compartment (4 more inside the membranes) via a backwash pump P2 and a valve V3.

Example 1 (comparative)
River water with a turbidity of 10 NTU and a total organic carbon content of 10 ppm is introduced at a flow rate of 1 m3 / h using a feed pump P1 through the upper end of a casing 1 containing a bundle 2 of outer skin polymeric hollow fibers with an external diameter of 1 mm, the total filtration area being 20 μm. The water introduced into the concentrated compartment 3 between the bundle 2 of fibers and the casing 1 passes through the wall of the membranes and is discharged through the internal channel thereof to the upper head 4 of the casing. It is sent to the permeate tank 5.

 At the beginning of the operation, the pressure measured in the crankcase is 150 000 Fa. As the filtration continues, the particles and dissolved species stopped by the tubular membranes accumulate on their outer surface. forming a brownish layer (it should be noted that the use of externally skinned fibers allows a visual examination of the state of fouling of the fibers during experiments carried out in a transparent housing).

 After 15 minutes of operation, 250 l of turbid water were filtered and the pressure in the crankcase reached the value of 157,000 m.

 The pump P1 for supplying turbid water is then stopped, the permeate tank 5 is isolated by closing the valve V2, the backwash pump P2 is started, which sends washing liquid, advantageously water which the it has just been obtained, and then opens the evacuation device (valve V1) concentrat compartment Cil there is no prior emptying thereof.

 Using a discharge valve V3 located at the discharge of the backwash pump P2, the backwash pressure is set at a value of 400 000 Fs.

This pressure is applied for 1 min, during which time 55 l of filtered liquid and 15 l of concentrate initially contained in the crankcase are used.

The filtration cycle is then resumed by stopping the backwash pump P2, closing the evacuation V1 of the casing and restarting the supply pump P1.
It is found that the initial pressure necessary to filter 1 m3 / h is 152 000 Fa and after 15 minutes it rose to 159 000 Fa. Then triggers a new backwash as before. Successive backwashing is carried out for 78 hours. At the end of this time, the pressure in the crankcase at the beginning of the filtration cycle is 170 000 Fa. The pressure at the beginning of the cycle after 78 h is therefore greater than that required at the start of the test (150 000 Pa). The rise in pressure over time is linear and is 256 Fa per hour of filtration. After backwashing, the fibers are still covered with a brown film.

Example 2 (according to the invention?
River water with a turbidity varying over time between 60 and 10 NTU and with a total organic carbon content of 1oppm is introduced at a flow rate of 1 m3Sh in the upper inlet of a housing containing a beam of hollow fibers identical to that used in Example 1. All the introduced water passes through the wall of the tubular membranes and fills the permeate tank 5.

 The initial pressure measured in the crankcase is 150 000 Fa. After 15 minutes of operation, 250 l of turbid water were filtered and the pressure in the crankcase reached the value of 160 000 fa. in the following manner: an stops the raw water supply pump Fi, opens the outlet valve V1 of the housing and the inlet valve V4 located at the upper part, so as to evacuate the concentrate contained in the housing (concentrat compartment 37.

 When all the liquid is evacuated, which takes about 30 seconds and represents a raw water loss of 15 liters, the backwash pump P2 is triggered with closing of the water inlet (valve V2 2 in the permeate tank 5. During 20 s, the backwash pump P2 applies a pressure of 400 000 Fa inside the fibers, 20 l of filtered liquid is then used, and during backwashing it is observed that the brown deposit found on the membranes is driven. by the liquid to the discharge outlet of the housing All the liquid that has passed through the membranes flows along them without filling the housing before being evacuated.

 After the 20 s of washing, the filtration is resumed leaving the air inlet valve V4 open for 1 min so as to expel the air contained in the housing. It can be seen that the pressure needed to filter 1 m3 / h is 150 000 Fa and that after 15 minutes it has risen to 160 000 Fa. A new backwashing operation is started as before. Successive backwashings were carried out for 144 hours. After 78 hours, the pressure in the crankcase at the beginning of the cycle is 153,000 F. There is therefore a slight increase in pressure over time, but much lower than in the preceding comparative example. The increase in pressure is linear and is 38 Fa per hour of filtration.

 After backwashing the fibers are white and no brown film is seen.

 After 144 hours, the crankcase pressure is 155,400 Fa.

Example 3
If in example 2 reduces the backwash pressure from 400 000 Fa to 250 000 Fa, the wash water consumption of 20 1 is reduced to 9 1. The rise in pressure over time is of the same order of magnitude than that found in Example 2.

 It can therefore be seen that with reduced water consumption, much better backwashing is achieved than in the comparative example.

 The preceding examples have been implemented with stopping the water supply to be filtered during backwashing, but this stop is not essential.

However, an additional advantage derives from the fact that when this feed is taken up again, the air or gas remaining in the crankcase at the end of washing is pushed under pressure towards an air outlet. If leaks exist at the top plate of the membranes, on the membranes themselves or at the level of the seal between the concentrate and permeate compartments, then air or gas bubbles are observed in the permeate compartment. This makes it possible to detect leaks if a portion of the permeate compartment is visible.

For the implementation of the three variants of step a) and the three embodiments of step b), one plays
for step a) on the opening of the valve V4 (first variant), on the injection of air or compressed gas upstream of the valve V4 which remains open (second variant), on the possible addition of a pump downstream of the valve VI the valve V4 is still open third variant>.

 for step b), on the pressure imposed by the pump P2 and the valve V3, on the addition of a pump downstream of the valve V1 and on their combination.

 In addition, the effectiveness of backwashing can be further improved by chlorinating the backwashing liquid as it has been found that such treatment improves the efficiency of backwashing of any type.

Claims (14)

 1.- Method for Cleaning Mesoporous Ultrafiltration Tubular Membranes Cincluant the hollow fibers) mounted in a bundle in a housing, with delimitation of a concentrated compartment where the suspended materials accumulate both in suspension and on the membranes and a permeate compartment collecting the filtered liquid, characterized in that it comprises the steps of  empty the concentrated compartment to evacuate the liquid to be filtered and the suspended solids, then  b) carry out a backwash by passage of liquid from the permeate compartment to the compartment concentrate through the membranes to take off and remove the impurities deposited thereon.  2. A process according to claim 1, characterized in that step a) is carried out by opening a discharge system of the concentrated compartment and a device for bringing the concentrated compartment to atmospheric pressure.  3. A process according to claim 1, characterized in that step a) is performed with the opening of a discharge system of the compartment concentrat and injection of a gas under pressure in said compartment.  4.- Method according to claim X, characterized in that performs step a? by sucking the concentrate through a system for evacuating the concentrated compartment and opening an atmospheric pressure device of the concentrat compartment.  5. A process according to any one of claims 1 to 4, characterized in that step b> is performed by injecting the washing liquid at overpressure relative to the air pressure (or gas) that prevails in the concentrated compartment.  6. A process according to any one of claims 1 to 4, characterized in that in step b), the concentrated compartment is placed under partial vacuum.  7. A process according to any one of claims 1 to 4, characterized in that step b) is performed by injection of washing liquid under overpressure and partial vacuum concentration compartment.  8.- Method according to any one of claims 1 to 7, characterized in that performs step b? without supply of liquid to be filtered in the concentrated compartment.  9. A process according to any one of claims 1 to 7, characterized in that performs step b) with supply of liquid to be filtered in the concentrated compartment.  10. A method according to claim 8, characterized in that it detects any leaks at the membranes or their mounting to the housing, the recovery of the liquid supply to be filtered, by appearance of air bubbles or of gas in the collection compartment of the filtered liquid.  11. A process according to any one of claims 1 to 10, characterized in that the filtered liquid injected into phase b> is previously added with a chlorinating agent.  12.- Use of the method according to any one of claims 1 to 11, for cleaning outer skin tubular membranes, the concentrated compartment being constituted by the inner space of the housing around and between the bundled membranes and the compartment permeate being constituted by the interior of the tubular membranes  13.- Use of the method according to any one of claims 1 to 11 for cleaning tubular membranes with inner skin, the compartment concentrat being constituted by the inner space of the membranes and the permeate compartment by the inner space of the housing around and between the membranes.  14.- Use of the method according to any one of claims S to 11 for cleaning symmetrical or isotropic tubular membranes, the permeate compartment being constituted by the internal space of the membranes when the filtration is from the outside to the inside the membranes and by the inner space of the housing around and between the membranes when the filtration is from the inside to the outside of the membranes, the concentrated compartment being constituted by the other space delimited by the membranes.