KR820000468B1 - Process for removal of suspended solids from liquid - Google Patents

Abstract

In the removal of suspended solids from a liq. (wastewater or raw water being purified) by filtration in a fitration vessel contg. a bed of discontinuous polyurethane foam particles, the filter bed is regenerated by adding >= 1 bed vol. of a regeneration liq. to the filter vessel, mech. mixing the regeneration liq. with the filter bed particles, and discharging the solids-enriched liq. from the vessel. In a test with a filter used for the treatment of wastewater, 4.5 gal of regeneration liq. was required and 97.5% solids removal was obtained, compared with 14gal and 72%, resp., for regeneration by backwashing.

Description

How to remove suspended solids in liquid

1 is a schematic representation of a filtration layer comprised of discrete polyurethane particles that may be suitably used in the practice of the present invention.

2 is a schematic diagram illustrating the step of regenerating the filtration layer of FIG.

3 is a schematic diagram showing that another embodiment of the invention lies a filtration layer composed of discrete polyurethane particles lying upstream of a conventional sand filtration layer.

The present invention relates to a method of removing solids by passing a liquid in which solids are suspended through a filtration layer of discontinuous polyurethane particles.

In the field of water and wastewater treatment, filtration has long been used mainly as a method for removing solids in liquid phases. Especially in the wastewater treatment, the presence of suspended solids is often a process problem, and filtration is intended for municipal sewage or regeneration. It has been adopted as a method for removing or reducing solids suspended in wastewater. In such cases, top-down and bottom-up sand filtration layers and double or mixed filtration were widely used and generally brought about in terms of efficiency. Nevertheless, field workers have found that sand and mixed filtration layers have been applied only to limited solids treatment conditions, although they are generally effective in removing suspended solids. Typically, the concentration of solids in the liquid entering the filter bed should be about 100-200 mg / l or less. If the concentration of the spherical content is larger than this value, the filtration layer is blocked, causing a large pressure drop over the entire filtration layer.

Recently, the filtration operation has been somewhat improved by using polyurethane as a medium. In a general practice, the filter layer was foamed by crushing the expandable polyurethane into pieces and introducing them into the treatment vessel. Wastewater or other liquids containing suspended solids were then passed through the filter bed to cause the suspended solids to adhere to the polyurethane particles. The liquid containing the suspended solids and the suspended solids remaining on the polyurethane particles in this way passes through the filtration layer and is released as a liquid phase from which the suspended solids are removed.

In general, the use of foamed polyurethane as a media has several advantages over sand or conventional mixed filtration materials. For example, a large volume of solids that can be treated and a small pressure drop are blocked. It is lighted that this prevents and many kinds of soluble organic contaminants can be removed from the liquid. Despite this many advantages, however, the regeneration of the foamed polyurethane with suspended solids during filtration has led to serious operational problems. Several schemes have been proposed for the regeneration of an expandable polyurethane filtration layer in which at least a portion of the filtration operations are loaded with suspended solids, for example by a solid-free liquid such as those commonly used in conventional sand and mixed filtration systems. (Iii) washing. In the foamable polyurethane filter layer, the backwashing method has a special problem because the density of the foamable polyurethane filter medium is low.

Since the true density of polyurethane is as low as 1-2 lb / ft ³ , it is preferable to allow the liquid containing suspended solids to pass the foamed polyurethane filtration layer downward in normal operation. Backwashing the filtration layer causes a clean liquid to flow countercurrently upward of the filtration layer, which generally requires a high flow rate to wash the foamed polyurethane particles from the filtration layer and leaves many voids in the filtration layer. Filtration can bypass or otherwise cause operational deficiencies. On the other hand, if the polyurethane filtration layer is regenerated by the same method as flowing the liquid from which the suspended solids have been removed below the solid packed layer as in the usual filtration step, the suspension solids are sufficiently removed from the polyurethane particles and filtered after regeneration. It is generally difficult to satisfactorily use the filter bed in the step.

In the prior art, a method of compressing and regenerating polyurethane foam in the filter layer has been proposed in view of the above-mentioned difficulties due to the extremely low density of the foamable polyurethane media compared to the conventional backwashing of the foamable polyurethane filter layer and the conventional media. . This compression regeneration method generally uses a mechanical method to squeeze the polyurethane foam particles to squeeze the particles and water in the foam. While this regeneration method can be readily employed in the case of laboratory or bench-scale filtration devices, the mechanical complexity and cost of the device for squeezing the foam particles in a commercial scale polyurethane filtration layer is not a viable use of the polyurethane foam filtration layer. It was very restrictive.

It is therefore an object of the present invention to provide an advanced method for removing suspended solids attached from polyurethane in a filtration layer consisting of polyurethane particles.

Another object of the present invention is to provide a process with a very low volume of regeneration liquid required, and the advantages of the present invention will become apparent from the following description.

The present invention relates to a process for removing floating solids with a liquid containing suspended solids.

In the process of the present invention, a filtration vessel containing a discontinuous polyurethane particle layer is provided. The liquid containing the suspended solids passes through the filtration layer in the filtration vessel to adhere the solids to the polyurethane particles to form a liquid from which the solids are removed, and the liquid from which the solids are removed is at least partially loaded with solids from which the filtration layer has been removed. Until it is discharged from the filtration vessel. The passage of the filtration layer of the liquid is stopped. The adhered solid is removed from the discontinuous polyurethane particles in the filter layer to regenerate the filter layer to remove solids in the suspension.

In an improved aspect of the present invention, removing the adhered solids from the discontinuous polyurethane particles in the filter bed adds at least the same amount of regeneration liquid to the filter vessel as the volume of the filter bed and discontinuous polyurethane with solids attached thereto. Mechanically stirring the filtration layer of the particles, the total amount of liquid stops the flow of the liquid through the filtration layer in order to differentiate the solids attached from the regenerated liquid and the discontinuous polyurethane particles, and passes through the entire liquid, It is composed of a holder liquid that forms a rich liquid.

In a preferred embodiment of the present invention, the filtration layer accounts for less than 1/2 of the capacity of the filtration vessel and mechanical mixing is achieved by stirring the polyurethane particle filtration layer.

In another embodiment of the present invention, the regenerated liquid is 1-2 times the capacity of the filtration layer.

As used herein, the term "regeneration liquid" refers to a liquid that detaches solids attached from a suspended phase and is released during mechanical stirring of the polyurethane particle filtration layer. The term "hollow down liquid in the filtration layer" also means a liquid contained in the pores of the polyurethane particles of the filtration layer after the passage between the liquid between the polyurethane particles and the liquid in the filtration layer is completed. "Volume of the filtration layer" means the volume of liquid corresponding to the capacity of the filtration layer.

Referring to FIG. 1, the liquid containing suspended solids flows into the processing system through a conduit 100 in which a control valve 115 is installed, which is open at the beginning of operation. These liquids can come from a variety of sources, for example effluents from biological treatment plants containing 40-60 ppm suspended solids or river water used in municipal sewage treatment plants. Alternatively, this liquid may consist of feed water for boilers or plant water, and this liquid is also treated as an algae pond (oxidized ditch) to prevent pinpoint algae from reaching the collection water. It may be a stream of water. Liquid from conduit 100 enters container 102 and is discharged by a spray distributor or other discharge device 101 at the top of the container. The filter vessel 102 is suitably made of cast iron or other building material and is partially filled with the filtration layer 103 of discontinuous polyurethane particles, the reason for which will be apparent below.

The filter vessel is provided with an inlet at the top and an outlet at the bottom. The discontinuous polyurethane particle filtration layer is supported by a lower support 104 which is composed of a net membrane or other fine material. In this way, a plenum space 105 is formed in the lower portion of the vessel 102, where the liquid passing through the filtration layer is collected.

The liquid containing the suspended solids flows from the upper inlet of the filtration layer of the filter vessel to the lower outlet to attach the solids in the liquid to the polyurethane particles. The solids formed in this way are collected in the lower plenum space 105 and discharged from the filtration vessel through a conduit 106 provided with a control valve 116. Liquid with solids removed from conduit 106 is used through water reservoirs and / or other treatment devices.

The flow of suspended solids-containing liquid as described above continues until the filtration layer is loaded with at least partially attached solids, stops the passage of the liquid through the filtration layer and then the filtration layer is regenerated.

In the above-described systems, it may be desirable in some cases to add an organic polymer flocculant or a flocculant such as sodium silicate or alum to the liquid entering the filtration layer in order to promote the solids collection removal efficiency of the filtration layer. These flocculants are needed in some cases to increase the aggregation of suspended solids in the liquid to be treated and also to reduce the turbidity of the liquid finally discharged from the filter bed treatment system.

The polyurethane particles employed in the filtration layer of the present invention may be in the form of a suitable foam having a solid load capacity corresponding to the filtration operation time employed. The discontinuous polyurethanes used as particles in the filtration layer are in the form of particles of pulverized non-uniform size or cubes, which are small cubes of cubes made of foamed polyurethane having a length of 1 / 4-1 ". In practice, suitable foamable polyurethane materials which have been successfully employed have a cell density of 10-1000 cells / 1 nch.

The true density of the polyurethane particles in the filtration layer should be 1.341b / ft ³ or more to maintain the structural strength of the filtration layer and to prevent the polyurethane particles from floating up during filtration. The polyurethane particles in the filtration layer preferably have a solid load capacity of at least 1 / 21b suspended solids / (polyurethane particles 1ft ³ ) to provide an appropriately high solid load capacity during filtration.

For example, the expandable polyurethane used in the present invention may be in a pulverized form, having a particle length of 1-2 ", 30 cells / inch, a particle thickness of about 0.25", and an abundance (not including pores) of 1.771b. / ft ³ , tensile strength is 23.5pi. The volumetric flow rate of the suspended solids-containing liquid passing through the filtration layer during the filtration step is maintained at 1-10 gallons per minute (filtration layer cross-sectional area ft ² ) so that the liquid within the filtration layer is in proper contact with the polyurethane particles and bypasses or otherwise. It is good practice to prevent unintended flow. After the filtration layer is loaded with at least partially attached solids, the attached solids are removed from the discontinuous polyurethane particles in the filtration layer, thereby regenerating the filtration layer for removing solids from the liquid containing suspended solids.

The flow of liquid through the filtration layer 103 is stopped before the regeneration step, for example by closing the control valves 115 and 116 installed in the conduits 100 and 160. After the liquid flow in the filtration layer is stopped, the holder liquid remains in the filtration layer 103. In the regeneration step, regeneration liquid of at least the same filtration layer volume is supplied to the filtration vessel 102 to form the total liquid volume consisting of the regeneration liquid and the holder liquid in the filtration vessel. 2 shows the filtration vessel of FIG. 1 in which the filtration vessel contains the above-mentioned total liquid volume. Before adding the regenerated liquid to the filtration vessel, the filtration vessel generally contains sufficient Hollow liquid to constitute most of the filtration liquid due to the high porosity of the polyurethane particle filtration layer.

For example, the porosity of the polyurethane particle filtration layer is about 80%, and when the flow of liquid through the filtration layer is stopped, the filter vessel may contain 0.8 filtration volume of liquid in the pores between and within the polyurethane particles. Will be.

As mentioned above, the term "filtration layer volume" refers to the volume unit of liquid corresponding to the volume of the filtration layer. Therefore, if the filtration layer is 2ft high in the filter vessel, the liquid level in the mixture of polyurethane particles and liquid phase will be 4ft in the filter vessel when a liquid (regeneration liquid) corresponding to the same filtration layer volume is added.

The regeneration liquid applied to the filtration vessel in the regeneration step is composed of suspended solids-containing liquid introduced through the conduit 100, and then the valve 115 installed in the conduit 100 is closed. The regenerated liquid is also composed of a liquid from which solids have been removed. For example, when the liquid containing the suspended solid is water, clean water is used. The solids-removed liquid may flow in countercurrent to the filter layer after the liquid flow in the filter layer is stopped, and the regeneration liquid may flow countercurrently through the conduit 113 in the conduit 106 immediately below the filter vessel 102. To the part. In the latter case the valve 114 in the conduit 113 is opened and the valve 115 in the conduit 100 and the valve 116 in the conduit 106 are closed.

During the normal filtration step, valve 114 is closed while valves 115 and 116 are open. Opening and closing of each of these several valves is performed by a cycle time control system of the type well known to those skilled in the art.

All valves 114, 115 and 116 are closed as shown in FIG. 2 after at least the same regeneration liquid of the same filtration layer volume is applied to the filtration vessel. Preferably, as shown in FIG. 1, the filtration layer is filled by 1/2 or less of the volume of the filtration vessel so that the regeneration liquid of at least the same volume of the filtration layer flows into the filtration vessel. As described above, in the regeneration step, the filtration vessel contains a total volume of liquid consisting of the regeneration liquid and the residual holder liquid after passage.

In the general practice of the present invention, the residual Houlup liquid after the liquid in the filter layer is interpreted in a broad sense, and the Houlup liquid and the polyurethane in the filter layer composed of the solid-removed liquid remaining after the liquid flow in the filter layer is stopped. It consists of the liquid remaining between the pores of the polyurethane particles when the liquid between the particles and the liquid passing through the filtration layer is completed and the liquid in the filtration layer is discharged. Replaced by a part. In other words, in the broad practice of the present invention, after the filtration step, the liquid in the container is completely removed, and then the filter container is filled with the regeneration liquid so that a part of the total liquid volume is previously contained in the voids between the polyurethane particles and the inside of the particle. Can be replaced.

In this way, a part of the volume of the filtration layer of the regeneration liquid filling the internal voids between the polyurethane particles of the filtration layer becomes a hole liquid in the filtration layer. Nevertheless, in order to shorten the regeneration time of the filtration layer and to simplify the regeneration process, it is generally good to retain the holder fluid remaining after the passage of the liquid through the filtration layer.

In the system shown in FIG. 2, the regenerated liquid flows into the filtration vessel to form the entire liquid volume consisting of the regenerated liquid and the hollow liquid, and then the discontinuous polyurethane particle filtering layer to which the solids are attached is mechanically mixed. The adhered solids are detached from the particles and included in the whole liquid to form a liquid having solid content strengthened. This is performed by operating the motor device 117 to which the rotating shaft 118 is connected to rotate the propeller 119. After agitation for a suitable time (e.g. 1-3 minutes), the solids attached from the polyurethane particles are released and the motor drive 117 is stopped and a high solids liquid is opened from the vessel through the conduit 106. Is discharged to the valve 116.

The liquid in the conduit 106 having a high solids content may be further processed or fed to a final treatment device, such as a sludge dry bed. After the liquid with a large solid content is completely discharged from the filtration vessel, the filtration layer is regenerated and re-filtered. This opens the valve 115 attached to the raw material liquid supply conduit 100 to remove the liquid containing the suspended solid. It begins by feeding into filtration vessel 102.

As described above, the regeneration liquid is preferably 1-2 times the volume of the filtration layer. The volume of such regeneration liquid is sufficient to completely regenerate the polyurethane particle filtration layer in the broad practice of the present invention. For example, foamed polyurethane and the length of the filtration layer have proven to be capable of regenerating satisfactorily with 30 cells per inch of regeneration liquid (other than Hollow liquid in the filtration vessel) of the same filtration layer volume. have.

On the other hand, 60 cells per inch in the length of the foamable polyurethane filtration layer were found to require 1.6 times the volume of regeneration liquid (in addition to the Hollow liquid in the filtration vessel) for effective regeneration. This difference is due to the fact that 60 foamable polyurethane cells are less dense than 30 foamed polyurethanes, so that the electrons in the regeneration step require more mechanical mixing.

3 shows a schematic of another process for the practice of the present invention. The liquid containing suspended solids is supplied to the conduit 200 in which the control valve 215 is installed, and the filtration layer 203 filled with discontinuous polyurethane particles through the distribution device 201 at the top of the filtration vessel 202. Inflow). The filter layer of discontinuous polyurethane particles has an inlet at the top and an outlet at the bottom and a base plate 204 at the bottom to provide a plenum space for trapping the purified liquid exiting from the filter layer at the bottom. . The liquid containing the suspended solids flows into the filtration layer of the filtration vessel and the solids adhere to the polyurethane particles to form a liquid from which the solids are removed. In this way, the liquid from which the solids have been removed is discharged from the filtration vessel 202 through the conduit 206, and during the normal filtration step, the valve 215 of the conduit 200 is opened and the valve 209 of the conduit 208 is closed. .

The liquid with solids removed from conduit 206 is fed to downstream filtration layer 237 for final processing. The downstream filtration layer 237 is contained in the vessel 236 and the liquid in the conduit 206 flows through the dispensing device 235, which is similar in shape to that used for the filtration vessel 202.

The liquid passing through the downstream filtration layer 237 is discharged through the conduit 238 and stored in a water reservoir or for other desired uses.

The filtration step described above is continued until at least a portion of the filtration layer is loaded with attached solids to stop the passage of the liquid in the filtration layer. The filtration layer of the polyurethane particles is regenerated by removing solids adhering to the discontinuous polyurethane particles, thereby regenerating the filtration capacity of the filtration layer which removes solids in the liquid containing suspended solids.

In the regeneration step, regeneration liquid of at least the same filtration layer volume is supplied to the filtration vessel 202. The solid polyurethane particle filtration layer with solids attached is mechanically mixed by stirring by rotating the impeller 219 connected to it by the shaft 218 by operating the motor driving device 217. The mixing agitation is carried out for a suitable time, for example, 1-3 minutes, with a total liquid consisting of retentive liquid and retained liquid remaining after liquid stoppage of the filtration layer to remove the adhered solids from the discontinuous polyurethane particles. It penetrates into the whole liquid and eventually forms a solid-enriched liquid. At this time, the valve 209 in the conduit 208 is opened and the liquid having a large solid content is discharged from the filtration vessel through the conduit 208, so that the filtration layer 203 in the container is regenerated so that the filtration operation can be performed again. The second filtration layer 237 can be regenerated by any suitable method such as conventional backwashing or the like.

The advantages of the invention are illustrated in the following examples.

EXAMPLE

The operation efficiency was evaluated by comparing the case of back washing with the filtration layer and the case of regeneration by the stirring mixing method of the present invention. In performing evaluation, two filter layers were installed in parallel and the same amount of solid wastewater was passed through. Each filtration layer is contained in a vitreous column with an inner diameter of 14 cm. They contained 75 g of expandable polyurethane with porosity of about 95% and 60 cells per inch in length, the height of the filtration layers were 23 cm each and the packing density was 30 g of the expandable polyurethane per liter of filter layer volume.

Each filter bed was passed a liquid containing 200 ml of suspended solids per hour. Four separate regenerations were performed between the filtration stages and the fourth operation was considered to represent steady-state operating conditions. Each filtration step was carried out for 8 hours. After completion of the filtration step, one of the filtration layers was regenerated by back washing and another filtration layer was regenerated by the exchange mixing method, which is the method of the present invention.

In the regeneration step by back washing of the first filtration layer, clean water flowed through the filtration layer in the direction of flow (downward) and countercurrent of the liquid passing through the filtration layer as a back washing medium in the normal filtration step. At the backwash stage, the backwash flow rate was 18 gallons per minute (filtration bed area ft ² ) and regeneration was carried out for 5 minutes, with no backwash flow.

In the filter layer regenerated by the method of the present invention, a regenerated liquid (clean water) having the same volume of the filter layer is supplied into the filter vessel, and the filter layer is composed of the remaining hole-flop liquid when the regeneration liquid and the filter layer solution are stopped. Mechanically mixed in the entire liquid. After the regeneration liquid was added, the filter layer was stirred for 2 minutes with an impeller having a pitch of 45 °. The diameter of the impeller was about 5cm and the rotation speed of the impeller was about 100-200rpm during mixing.

After the mixing stirring was stopped, the liquid in the filtration layer was drained. The filter layer was then further charged with clean water corresponding to twice the volume of the filter bed and then mechanically mixed for another 2 minutes. Filtration was resumed after mixing was completed again.

The efficiency by each regeneration method was summarized in Table 1 below and compared.

TABLE 1

As shown in the above data, a total of 14 gallons of regeneration liquid is required for the regeneration method by back washing, whereas only 4.5 gallons are used in the stirring mixing method of the present invention. The total amount of regenerated liquid shown in Fig. 1 is composed of the amount of regenerated liquid applied and the hole liquid contained in the pores and pores of the filtration layer).

In addition, as shown in the above table, despite using a large amount of regenerated liquid by backwashing, only 72% of the solid content was removed from the filtration layer, whereas it was 97.5% when regenerated by the stirring mixing method of the present invention. Solids were removed.

Although preferred embodiments of the present invention have been described in detail, devices that slightly refine the method are also within the scope of the present invention.

Claims (1)

In order to remove the suspended solids in the liquid, the solids in the suspension are attached to the particles by using a filtration layer filled with discontinuous polyurethane particles to remove the solids, and then the flow through the filtration layer is stopped and the reclaimed liquid is added to remove the solids. In the filtration method of regenerating the filtration layer by desorption, the filtration layer is less than 1/2 of the total filtration vessel, and at least a regeneration liquid corresponding to the volume of the filtration layer is removed for removal of adherent solids, followed by The filtration layer is mixed by mechanical agitation, where the total amount of liquid is 1-2 times the volume of the filtration layer, and the attached solids are detached from the polyurethane particles and incorporated into the liquid without removing liquid from the filtration vessel during mechanical mixing. Suspended solids characterized by forming a fortified liquid and then discharging it from the filter vessel Method of removing solids from a liquid.

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