KR19980076584A - Separation method and apparatus - Google Patents

Abstract

And separating the particulate material suspended in the liquid from the liquid. The method includes the steps of providing at least one upright tubular filter unit having an upper end and a lower end, introducing a flow of suspension into the tubular filter unit at one end thereof, and causing the suspension to pass through the tubular filter unit, And capturing the particulate material. Devices for practicing the method of the present invention are also described.

Description

Separation method and apparatus

The invention relates to separation.

Separation by filtration is a widely used method for separating the granular solids suspended in the liquid medium in the liquid medium. It has been particularly applied to the purification of water.

Filtration can use various filter media such as sand, fabric, paper, and the like. One such filter medium is a filtration tube, in which the suspension is introduced into the tube and the liquid is forced out to capture the particulate matter on the tube surface. The columns of the tube can be used. It is customary to use such pipes in a horizontal or essentially horizontal arrangement.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a process flow diagram illustrating the method of the present invention and the apparatus for carrying out the method of the present invention.

2 is a cross-sectional view of a tubular filter unit inflated to a pressure exerted therein from a suspension flowing through a tubular filter unit before particulate matter is captured on the inner surface of the tubular filter unit.

3 is a cross-sectional view of a tubular filter unit after the particulate matter has been captured on the inner surface of the tubular filter unit.

Figure 4 shows a flat filter cake as a cross-sectional view of the folded tubular filter unit of Figure 3 after the vacuum is applied to the inner surface of the tubular filter unit.

Fig. 5 is a cross-sectional view of the tubular filter unit of Fig. 4, with the side of the tubular filter unit being inflated and separated from the flat filter cake by a pulsed flow of suspension through the tubular filter unit.

According to one aspect of the present invention, there is provided a method of separating suspended particulate matter from a liquid

Providing at least one upstanding tubular filter unit having an upper end and a lower end,

Introducing a flow of suspension into the tubular filter unit at one end thereof, and

Allowing the suspension to pass through the tubular filter unit and capturing particulate matter on its inner surface

.

The method may also include the step of collecting the clarified liquid from which the particulate material has been separated on the outer surface of the tubular filter unit.

The liquid suspension is preferably introduced into the upper end of the tubular filter unit.

The suspension may be passed downward in the tubular filter unit under the influence of gravity.

The present invention may also include the step of removing particulate matter trapped on the inner surface of the tubular filter unit.

The tubular filter unit preferably comprises a flexible side wall.

The step of removing the particulate material

Stopping or reducing the flow of suspension to the tubular filter unit, and

Ejecting liquid from within the tubular filter unit to deform the flexible sidewall of the tubular filter unit so that at least a portion of the captured particulate material is removed

. ≪ / RTI >

Preferably, the upper end of the upright tubular filter unit is sealed or substantially sealed.

Preferably, the interior of the tubular filter unit is exhausted sufficiently to create at least a partial vacuum inside the tubular filter unit.

The deformation of the tubular filter unit is preferably to flatten the flexible side walls of the tubular filter unit with internal vacuum to compress the trapped particulate material into a flat cake.

The step of removing trapped particulate material may also include introducing a new flow of suspension into the exhausted tubular filter unit.

The new flow of suspension is preferably introduced into the upper end of the exhausted tubular filter unit.

The new flow of suspension may consist of at least one pulse flow of the suspension. More preferably it consists of from one to four pulse streams of the suspension.

According to another aspect of the present invention there is provided an apparatus for separating suspended particulate matter from a liquid suspended in a liquid, the apparatus comprising at least one upright tubular filter unit having an upper end and a lower end, and means for closing the upper end thereof.

The means for closing the upper end of the filter unit is preferably a valve.

The apparatus may also include means for closing the lower end of the tubular filter unit, which may also be a valve.

The apparatus may include at least two adjacent upright tubular filter units.

DETAILED DESCRIPTION OF THE INVENTION [

A method of separating the suspended particulate material from the liquid suspension is described. The method involves utilizing at least one, but typically heat of the upright tubular filter unit, each having a top end and a bottom end. The flow of suspension is introduced into the upper end of each tubular filter unit and passed through a filter unit to capture the particulate matter on the inner surface of the filter unit. It is a very important feature of the method and apparatus of the present invention that each tubular filter unit is an upright unit. Each filter unit can be arranged or arranged vertically or nearly vertically.

It has been found that the upright arrangement or arrangement of each filter unit has many advantages. The upright arrangement or arrangement allows effective filtration by promoting good flow of the suspension through each filter unit under the influence of gravity. It also allows a vacuum to be created inside each filter unit by effectively exhausting each tubular filter unit, making it very easy to remove trapped particulate matter from the tubular filter unit as discussed more fully below. It has also been found that the upright arrangement of the tubes in the present invention facilitates folding of the tubes in vacuum, while the horizontal arrangement or arrangement of the tubes will be difficult to achieve such folding in vacuum.

The method of the present invention essentially involves a combination of three steps that are performed sequentially to remove particulate matter in the form of a filter cake captured on the inner surface of the tubular filter unit. In these three steps, the side wall of the filtration tube is deformed before and during the capture of the filter cake on the side wall of the filtration tube, and the vacuum is created in the tubular filter unit so that the cake and the filtration tube are folded inward, Forming a filter cake layer, and finally removing the trapped flat filter cake from the inner surface of the tubular filter unit by pulses or pulses of suspension to inflate the sidewall of the filtration tube.

The method and apparatus of the present invention will now be described in more detail with reference to the accompanying drawings.

The dehydrating sludge or slurry containing the suspended particulate material, i.e. the liquid suspension, is fed from the source 10 to the feed tank 12 along the line 14. It is fed through the line 30 through the pressure pump 28, To the row (32) of the upright tubular filter unit. There may be a plurality of rows in which the suspension is pumped, as shown by the dashed lines. In the drawing, only one row of the upright tubular filter units 31 is shown by solid lines. Each tubular unit 31 has an upper end 36 provided on the support manifold 38 and a lower end 40 provided on the support manifold 42 as well. The upper end is closable by a valve 56 and the lower end is also closed by a valve 44. If the pump used is a so-called rotary cavity pump, for example MONO ^{, a} pump, the flow of suspension to each upright tubular filter unit needs to be equipped with a valve 56 closing the upper part of the upright tubular filter unit or each upright tubular filter unit Can be stopped without.

The suspension supplies the upper portion 36 of each upright tubular filter unit 31 closed at its lower end by the pump 44, along the line 30, by the force of the pump. It fills the interior 46 of the tubular filter unit 31. Whereby the flexible side walls of the tubular filter unit are unfolded and expanded to assume a generally circular shape as shown in Fig. As the internal pressure of the tubular filter unit increases, the flexible sidewalls of the tubular filter unit are slightly laterally stretched and extended, while the granular material is trapped and attached while the flexible sidewall is in this stretched state. When the lower end (40) of the tubular filter unit is closed by the valve (44), the liquid in the suspension is forced through the porous sidewalls of the tubular filter unit to filter and purify the liquid. The clarified liquid descends on the outer surface of the tubular filter unit and is collected in a tray 48 located next to each tubular filter unit or column of tubular filter units for use or further processing.

Each tubular filter unit has a flexible sidewall 34 made of a material that is sufficiently flexible to allow the filter unit to fold as the filter unit is evacuated or emptied, as discussed more fully below. Suitable flexible materials can be paper, textiles, or another fabric of natural or synthetic origin. The material must be liquid permeable and the pores must be small enough to capture particulate matter.

The particulate material in the suspension is trapped in and on the flexible sidewall inner surface 50 of each tubular filter unit so that a filter cake layer is formed on the inner surface of the flexible wall of the tubular filter unit, (51). This filter cake layer should be removed occasionally to prevent the attachment to the tubular filter unit from becoming fully clogged and causing the tubular filter unit to become clogged or occluded and become ineffective or inoperative.

The filter cake layer is first removed by closing the valve 56 to neutralize the pressurized flow of the suspension to the tubular filter unit or each tubular filter unit. The valve 44 in the tubular filter unit lower end 40 is then opened to allow the tubular filter unit or each tubular filter unit to quickly and nearly completely discharge the liquid therein. Because of this rapid or sudden discharge, Vacuum is created inside the cylindrical filter cake tube. This vacuum sucks the flexible side wall of the tubular filter unit and becomes flat. Also by the vacuum, the trapped, tacky filter cake tube 51 is folded over itself and pressed into a flat cake 53 which is fitted in a flat tubular filter unit as shown in Fig. The external pressure of the flattened sidewall of the tubular filter unit and the vacuum force cause internal coupling of the cake layer. Due to the creation of vacuum, air can be sucked along the length of the filtration tube to further remove the cake from the tubular filter unit or each tubular filter unit.

Also, the sudden reduction of the pressure in the tubular filter unit may cause the flexible side wall to contract particularly rapidly in the longitudinal direction. This reduction assists in removing the trapped filter cake layer from the inner surface of the tubular sidewall because shear occurs between the inner surface of the sidewall of the tubular filter unit and the tubular filter cake to remove the tubular filter cake from the inner surface of the filtration tube to be.

The flat, removed filter cake layer is then removed from the interior of the tubular filter unit by opening valve 56 and then introducing a new flow of suspension into the flattened and vented tubular filter unit into the one to four pressurized pulse flows of the suspension Remove. The flow of fresh suspension collides with the top of the flat filter cake to cause the suspension to flow around the flattened removed filter cake side thereby inflating the flexible sidewall of the tubular filter unit and again creating a generally tubular contour as shown in Figure 5 Which makes it relatively easy to remove or flatten the removed filter cake from the interior of the tubular filter unit. This is called pulse cleaning or pulse washing.

The pressurized pulse flow of the suspension through the interior of the tubular filter unit is initiated by the wash pump 55 with the valve 56 closed and then the desired number of pressurized pulse flows through the tubular filter unit or tubular filter unit By opening and closing the valve 56 for a corresponding number of times. If the filter cake layer is thick enough, usually only one pulse layer will remove the filter cake layer.

The method of the present invention can be performed sufficiently well without requiring any additional cake removal means, but other cake removal methods may be used in connection with the presently described method. Such removal methods usually involve some externally applied pressure, typically a compression pressure. One of these methods entails placing a pair of rollers 52 next to each tubular filter unit. The rollers are moved inwardly to compress or squeeze the sidewalls of each tubular filter unit, thereby deforming or further deforming the sidewall to assist in removing or removing the cake from the sidewall. The roller is moved below the full length of the sidewall of the tubular filter unit to assist in squeezing particulate matter out of the lower end of the tubular filter unit. The roller then returns to its rest position, as shown in Fig. 1, and the filter unit prepares for an additional filtration or particulate matter removal cycle.

The removed cake falls onto conveyor belt 54, which is perforated so that the cake remains on the belt surface while the liquid in any removed cake and the liquid from the pulse flow are drained. The liquid is collected in the recycle feed tank 12 through the belt.

The method and apparatus of the present invention are particularly applicable to the purification of water or wastewater and the dehydration of sludge. The method and apparatus of the present invention have found that the method and apparatus of the present invention are particularly suited for the production of 15 to 35% solid cakes by dehydrating tap water and plant and mineral slurries containing solids from 5 to 50 g / l. The method and apparatus may also be used to purify turbid water to produce purified water suitable for human consumption or to purify plant effluent prior to drainage or further use of the effluent.

The method of the present invention will now be described with reference to the following exemplary embodiments.

Each having a diameter of about 63 mm and a length of about 2300 mm. Each filter tube is made of polyester of talc.

A suspension in the form of a water sludge having a solid concentration of about 10 to 30 g / l is introduced into the top of each filtration tube. The sludge is supplied to each tubular filter unit at a pressure of about 300 kPa for about 30 minutes after closing the lower end of each tubular filter unit.

Next, the sludge supply to each filter unit is stopped, and each filter unit is evacuated. The three independent pulses of the new sludge are then introduced into each filtration tube at a flow rate of about 6 m3 per hour per tube for a period of about 5 seconds per pulse.

The tube was thoroughly cleaned and found that 85 kg of cake had been removed from 28 tubes. The cake was measured to have a solid concentration of 31% m / m.

Claims (20)

A method for separating suspended particulate matter from a liquid, the method comprising: Providing at least one upstanding tubular filter unit having an upper end and a lower end, Introducing a flow of suspension into the tubular filter unit at one end thereof, and Allowing the suspension to pass through the tubular filter unit and capturing particulate matter on its inner surface ≪ / RTI > The method according to claim 1, further comprising the step of collecting the separated purified liquid on the outer surface of the tubular filter unit. 3. A method according to claim 1 or 2, characterized in that a liquid suspension is introduced into the upper end of the tubular filter unit. 4. A method according to any one of claims 1 to 3, characterized in that the suspension is passed downwards in the tubular filter unit under the influence of gravity. 5. The method according to any one of claims 1 to 4, further comprising the step of removing trapped particulate matter on the inner surface of the tubular filter unit. 6. The method of claim 5, wherein the tubular filter unit comprises a flexible side wall. 7. The method of claim 6, wherein the step of removing the particulate material comprises: Stopping or reducing the flow of suspension to the tubular filter unit, and Ejecting liquid from within the tubular filter unit to deform the flexible sidewall of the tubular filter unit so that at least a portion of the captured particulate material is removed ≪ / RTI > 8. A method according to claim 7, wherein the upper end of the tubular filter unit is at least partially sealed. 9. The method of claim 8, wherein the upper end of the tubular filter unit is completely sealed. 10. The method of claim 9 wherein the interior of the tubular filter unit is vented sufficiently to create at least a partial vacuum inside the tubular filter unit. 11. The method of claim 10, wherein the deformation of the tubular filter unit comprises flattening the flexible sidewalls of the tubular filter unit with internal vacuum to compress the trapped particulate material into a flat cake. 12. A method according to any one of claims 9-11, wherein removing the trapped particulate material further comprises introducing a new flow of suspension into the exhausted tubular filter unit. 13. A method according to claim 12, characterized in that the fresh flow of the suspension consists of at least one pulse flow of the suspension. 14. The method of claim 13, wherein the new flow of suspension comprises one to four pulse flows of the suspension. An apparatus for separating particulate matter suspended in liquid from the liquid, the apparatus comprising at least one upright tubular filter unit having an upper end and a lower end, and means for closing the upper end thereof. 16. The apparatus of claim 15, wherein at least one upstanding tubular filter unit has a flexible side wall. 17. An apparatus according to claim 15 or 16, wherein the means for closing the upper end of the tubular filter unit is a valve. 18. Apparatus according to any one of claims 15 to 17, further comprising means for closing the lower end of the tubular filter unit. 19. The device of claim 18, wherein the means for closing the lower end of the tubular filter unit is a valve. 20. Apparatus according to any one of claims 15 to 19, comprising at least two adjacent upright tubular filter units.