SU955852A3 - Process for treating effluents containing phosphate - Google Patents

Description

This invention relates to biological methods for treating phosphate-containing wastewater.

Phosphates present in organic waste are not subject to wastewater treatment methods and are discharged into natural water sources, causing contamination.

A known method of purification of phosphate-containing wastewater, according to which the pH of the raw wastewater is adjusted so that it is in the range of 6.2 to 8.5, then the wastewater is mixed with activated sludge to form a LIQUID; this mixed liquid is aerated. so as to maintain the dissolved oxygen content in the mixed liquid equal to O, 3 mg / l, followed by the separation of phosphorus-enriched sludge from the mixed liquid to produce an effluent practically free of sludge. Phosphate-enriched sludge is treated in such a way as to lower the phosphate content before recycling to mix with the run-off waste water. For this purpose, the phosphate-enriched sludge is kept under anaerobic conditions for several hours in a combined phosphate stripper and sludge sludge . In a phosphate oleid vessel, it exfoliates and thickens, and the anaerobic conditions cause the release of microorganisms that absorb frsfat in the aeration zone, phosphates, which transfer to the aqueous phase to form a phosphate-rich upper layer. The phosphate-rich supernatant is fed to a phosphate precipitant, to which phosphate precipitates are added.

15 veils, for example lime ij.

The disadvantage of this method is its duration and technological difficulties of the process.

20

The closest to the proposed method is the treatment of waste water containing phosphate, by mixing them with an oxygen-containing gas and activated sludge in the aeration zone to form phosphate-rich sludge and separating it from a low-phosphate liquid with stripping zone maintaining the main part of the sludge

during anaerobic words with the withdrawal of phosphate-rich liquid from the upper section of the stripping zone, and sludge with reduced phosphate content from the lower section of the stripping zone and the supply of the indicated sludge to the aeration zone 2J 5

This method requires the addition of significant amounts of an aqueous medium with a low phosphate content and the use of two separate tanks, i.e. a leaching tank for phosphate and a settling tank in order to separate the soluble phosphate from the sludge.

The disadvantage of this method is not high enough wastewater treatment and its long term.

The purpose of the invention is to increase the degree of purification and reduce its time. g

This goal is achieved by the fact that jQ that treatment of waste water containing phosphate is carried out by mixing them with oxygen-containing gas and activated sludge in the aeration zone to form phosphate-enriched sludge and separating it from the liquid with a low phosphate content and then feeding it to the stripping zone with maintaining the main part of the sludge under anaerobic conditions with the withdrawal of phosphate-rich liquid from the upper section of the steam zone, and the sludge with reduced phosphate content from the lower section from the steam zone and feeding the specified and and to the aeration zone, while the Phosphate-enriched sludge is kept in a stripping zone for 2-10 hours with the supply of waste water with a low phosphate content and less than 200 mg / l of suspended solids to the lower section of the stripping zone for prod-40 Moving up through a part of the settled solid particles into the upper zone of the stripping column with the ratio of the volumetric rate of wastewater supplied to the lower part of the stripping zone to 45 of the volumetric rate, the phosphate enriched liquid removed from the upper zone of the stripper 0.7-2.0.

The method includes the steps of mixing the input stream of phosphate-containing waste water with activated sludge and oxygen-containing gas in the aeration zone and simultaneous circulation of one fluid in the direction opposed to the movement of the other fluid for a time active substances in waste water and calling. The consumption of microorganisms present in activated sludge, phosphate with the formation of aerated - 60 mixed liquid containing sludge enriched in phosphate. Phosphate enriched sludge is separated from the aerated mixed liquid to produce effluent practically free of phosphate.

that The separated phosphate-rich sludge is fed to the phosphate stripper zone and at least most of the sludge is under anaerobic conditions in order to release phosphate from the phosphate-rich sludge and produce both low phosphate and -: phosphate-rich liquids. The phosphate-rich liquid is discharged from the upper part of the indicated stripping zone, and the phosphate-depleted sludge is discharged from the lower part of the stripping zone. At least a portion of the phosphate depleted sludge is recirculated to the aeration zone in the form of the activated activated.

The released phosphate is countercurrently stripped from the sludge in the stripping zone. The residence time of the sludge in the stripping zone is 2-10 hours. A medium with a low content of phosphate and solids is introduced into the lower part of the stripping zone so that an upward flow carries at least part of the precipitated solids into the upper part of the stripping zone . In this way, the phosphate released from the spherical oryl solids is transferred to the ascending liquid, which ensures that the above liquid enriched in phosphate enters the upper part of the stripping zone. The concentration of suspended solids in the stripping medium does not exceed 200 mg / l, and the volumetric rate of the stripping medium introduced into the stripping zone is adjusted so that it is 0.7-2.0 of the space velocity of the phosphate-rich liquid, which is discharged from there.

The term sludge as used in the present text refers to a mixture of a liquid with solids, which is characterized by the presence of a solid phase of sludge and a liquid phase associated with it. The term Stripping medium with a low content of phosphate and solids refers to an aqueous or water-containing medium that contains a lower phosphate concentration than the isolated phosphate containing anaerobic sludge with which this medium is in contact, in particular, the stripping medium has a concentration of soluble phosphate below 30 mg / ji As indicated in the paper, the concentration of solids in the stripping medium should not exceed 200 mg / l. The term main part of sludge is used in this text to denote the part of sludge that is kept under anaerobic conditions in the stripping zone and refers to at least 50% sludge by weight.

Phosphate-enriched sludge, in which phosphate is present in KJiei ka microorganisms, in biological solids, it is maintained under anaerobic conditions, i.e. such that there is no significant measurable amount of dissolved oxygen in the liquid phase — precipitated sludge in the phosphate stripper for a period of time sufficient for the microorganisms to release phosphate into the liquid sludge phase. The resulting anaerobic sludge containing the released phosphate is countercurrently in contact with the stripping medium with a low content of phosphate and solids. The purpose of this contact is the transfer of soluble phosphate and anaerobic sludge into the fluid flow leaving the upper section of the stripping zone so that to carry out a high degree of enrichment with NINP phosphate liquid leaving the zone. The present invention is based on the fact that, the phosphate stripping zone can efficiently act according to the countercurrent extraction method in order to obtain higher phosphate removals. In the known methods, a phosphate stripping zone is used by various methods, as a mixed transfer zone, which is upstream in relation to the subsequent separation zone, or as a concentration zone, either in the presence or in the absence of circulating streams enriched in phosphate. The first method, as indicated, requires large streams of stripping water and large capital expenditures and is limited in terms of mass transfer efficiency by equilibrium "1I" effects, which do not allow for the high removal of phosphate. In the latter method, it is very difficult to obtain a fast and complete transfer of the isolated soluble phosphate from the precipitated, concentrated layer of sludge in the bottom part of the stripping zone to: the floating liquid located in the HaB xy of the sedimented layer. Regarding the latter method, it should be noted that it was previously believed that the concentration of precipitated solids is highly desirable or even necessary in order to obtain a dense compact solid mass and consequently create a highly anaerobic environment that promotes the efficient release of intracellular phosphate into solid microorganisms. suck It has now been found that an extremely high removal of phosphate from phosphate-rich sludge can be achieved by operating the frsfate stripping zone using a countercurrent kon- extraction method. centering without using concentration. In accordance with the invention, a stripping medium with a low content of phosphate and solids flows upward through the precipitated sludge so that the soluble phosphate which is separated by solids from the liquid to the liquid phase and that is removed into the liquid flowing upward and the liquid containing the phosphate that surrounds the particles the precipitated solids are settled as a result of this by a stripping medium with low content of phosphate and solids. In this way, the phosphate concentrated gradient between the precipitated solids and the surrounding liquid phase tends to continuously increase under the effect of the stripping medium in the phosphate stripper zone with obtaining a correspondingly high mass transfer rate of solids in the surrounding i-bone at the stripping stage. The mentioned elimination of the function of ending centering In the phosphate-i stripping zone, which is achieved in limited special intervals of the residence time of the sludge, is suspended in bathing substances in the stripping medium k. The ratio of the volume flow rate of the phosphate-rich liquid to the volume flow rate of the stripping medium, which were previously established, is also very advantageous because: it significantly reduces the size of the cross-sectional area of the phosphate stripper, for example, to 4, relative to phosphate stripping zones, which is designed to effect concentration. Thus, carrying out the process in accordance with the proposed method allows to significantly reduce the capital cost of the equipment compared to the known systems using the concentration stage. In accordance with the proposed invention, a stripping medium with a low content of phosphate and solids may be a process stream in a wastewater treatment process or, on the other hand. May be supplied from external sources outside the wastewater treatment process. Suitable internal sources for the stripping medium may be inflowing wastewater, such as the primary effluent resulting from the primary sedimentation of a wastewater syrup, the effluent containing almost no phosphate, and the phosphate-enriched liquid flowing from the upper section of the stripper. zones after it has been treated with a reagent

phosphate and scum phosphate were removed to condemn. Phosphate-enriched fluid flowing out of the phosphate stripping zone can be treated in some way to remove NIN from it and recycled to the main effluent stream or withdrawn from the system for another final placement and / or use.

Example 1. When conducting; Comparative evaluation tests use a pilot plant comprising four subzones mounted for direct movement of the gas-liquid flow with a clarifier combining the final batch of liquid. Each subzone has a volume of about 1,430 liters and dimensions; The length is 153 cm, the width is 122 cm and the height is 124 cm. The total volume of the aeration zone is 5750 liters and the depth of the liquid during the experiments is 76 cm. Each sub-zone is equipped with a surface aerator to mix the gases with the liquid, which is set in motion by an electric method. . The clarifier has a volume on the order of 6510 liters and a cross-sectional area of 3.58 m. The phosphate stripper used in this pilot plant has a volume of about 3,900 liters and a cross-sectional area of 2.64 m, the mixing tank and the floc cooler arranged in series

 downstream from the stripping zone for treating a phosphate-rich liquid that comes out of the upper part of the stripping zone. In this pilot plant, the mixing tank has a volume of 2160 liters with a cross-sectional area of about 0.24 MI and the flocculating vessel has Volume 766 Whether the cross-sectional area is 0.36 All phases of the comparative evaluation test The incoming stream of phosphate-containing wastewater is mixed with recycled activated sludge to form a mixed liquid that is then oxified in the aera zone ii ,, in order to cause consumed ix microorganisms pres .stvuyuschimi in the activated sludge phosphate. Phosphate-rich sludge is then separated from the oxygenated mixed liquid in the clarifier from the effluent, which is substantially free of phosphate. The separated sludge enriched in phosphate is passed to the phosphate stripping zone and precipitated there. Precipitated sludge maintained at

anaerobic conditions for a time sufficient to release phosphate and

Phosphate-enriched solids are sludge. The phosphate-rich liquid is removed from the phosphate stripping zone, mixed with a phosphate precipitant (lime1 in the above-mentioned fast tank).

the resulting phosphate is removed as waste chemical sludge in a flocculation tank, and the treated phosphate depleted liquid is recycled to the wastewater inlet line. The precipitated sediment with reduced phosphate content is removed from the phosphate stripping zone and the inlet of the waste water in the form of the aforementioned activated sludge is recycled to the line.

In the first phase of the comparative evaluation Test conducted in accordance with a known method, the precipitated sludge is concentrated in the phosphate otarki zone to form a floating liquid covering the thickened solid matter, and in this zone the stripping does not take place in the solid with the liquid.

In the second phase of the evaluation experiment, which is also carried out according to a known method, the precipitated sludge is concentrated in the phosphate stripper zone as before, with the formation of a floating liquid. A portion of the supernatant emerging from the stripping zone is withdrawn and injected into the phosphate stripper zone under a layer of settled concentrated anaerobic sludge. In this way, the floating fluid flowing upward through a layer of dense thickened solids promotes the transfer of phosphate from the layer of solids to the floating liquid.

In the third phase of the evaluation experiment conducted in accordance with the invention, the process is carried out according to the method according to which the liquid enriched with phosphate is withdrawn from the upper part of the stripping zone and subjected to chemical treatment and sedimentation in the rapid mixing tank and flocculator, respectively, the formation of a phosphate depleted liquid, at least part of which is used as a stripping medium with a low phosphate content and a low solids content.

The fourth phase of the evaluation experiment is also carried out in accordance with the invention according to the method according to which a small part, i.e. less than 50% by volume, a substantially phosphate-free effluent, is introduced into the lower part of the stripping zone as a stripping medium with a low phosphate content and low solids content.

The duration of the test in the first phase without anaerobic contact is 8 days of continuous operation, and the second phase in which the contact of anaerobic contact with recycled supernatant liquid is used is continuous for 21 days. Tests in the third and fourth phases, which represent practical examples of use in accordance with the present invention, are carried out continuously for 11 and 22 days, respectively. The data obtained during the comparative evaluation test of the system described above is presented in tab. 1. These data demonstrate a significant improvement in the efficiency of phosphate removal, which will be achieved by the proposed method. Example 2. A pilot unit is used that has an aeration zone, 1 including six subzones, through which a mixed fluid passes successively, which is subjected to aeration in them with diffusing air according to a known method. This setting also has a clarifier attached to the last subzone. Each subzone has a cylindrical shape and has a volume of 37.8 liters and dimensions: a height of 152.5 cm and a diameter of 20.4 cm. The total volume of the aeration zones is 226 liters, and the depth of the liquid layer during the test is 122 cm. , 78 liters and a cross-sectional area of 0.14 m. The phosphate stripping zone used in this pilot plant has a volume of 78 liters and a cross-sectional area of 0.14 m. In both phases of the comparative assessment test, the incoming phosphate-containing wastewater is mixed with the recycled activated island to form a mixed liquid. which is aerated in the aeration zone so as to cause the consumption of microorganisms present in the activated sludge 7 phosphate. Then, the phosphate enriched OSTROY is separated from the aerated mixed liquid in the clarifier to obtain fflyuenta substantially free of phosphate. The separated sludge treated with phosphate is passed to the phosphate stripping zone and precipitated. Sludge is maintained under anaerobatic CONDITIONS for a time sufficient to release phosphate from the solid phase enriched in phosphate. Phosphate-enriched fluid is discharged from the upper part of the phosphate extraction stage and sludge with a low phosphate content is removed from the phosphate stripper zone and recycled. Into the sewage entry line in the form of activated sludge mentioned above. In the first phase of a comparative assessment test conducted in accordance with a known method, the precipitated sludge is concentrated in the phosphate stripper zone to form a floating liquid covering concentrated solids. A part of the concentrated precipitated sludge is withdrawn from the stripping zone, recycled along the line carrying sludge enriched in phosphate from the clarifier to the stripping zone, and mixed there with phosphate-rich sediment before feeding the combined stream to the stripping zone. This facilitates the transfer of phosphate from anaerobic concentrated sludge to the supernatant through recirculation contacting. In the second phase of the evaluation test, which is most relevant according to the invention, the process is carried out according to a method in which a small part, less than 50% by volume of incoming waste water, is introduced into the lower part of the stripping zone as a stripping medium with a low phosphate content and low solids content. The duration of the first test phase with recirculating contacting of the anaerobic sludge is 36 days of continuous operation, and the duration of the second test phase is 13 days of continuous operation. you. The data obtained in the course of a comparative evaluation test of the system described above is given in Table. 2. These data demonstrate a significant improvement in the efficiency of phosphate removal, which is achieved according to the proposed method: (data given in column E) compared with the known system (data given in column D). As can be seen from the above data, a contact stream is used in the known system (a stream of sulphate enriched in phosphate fed into the stripping zone, which has a high concentration of suspended solids in the order of 7940 mg / l. This stream, together with the recycled stream of anaerobic concentrated sate, forms a high load stripping solids, as a result of which, to obtain a total phosphate removal of 35.4%, a high correlation (1.7) of the flow rate of the contact flow to the volume flow is required of the upper stream (floating up liquid), as well as a relatively long residence time of sludge (8.2 h, calculated as the volume in the stripping zone divided by the volumetric flow rate of sludge with reduced phosphate content discharged from the stripping zone, which is recycled into aeration zone in the stripping zone. In contrast, the second phase system in accordance with the invention is able to give more than twice the phosphate utilization value compared to the first phase system (81.5%) with a low ootnoshe SRI space velocities (otparuoy cFe rows to the upper stream of the order of 0.73 and a residence time in the sludge to steam hydrochloric zone of 3.5 hours. Example 3. Comparative calculations performed by the cross sectional area of the stripping zone to the known and proposed systems. The known system is of the type described previously with reference to column B, which is characterized by contacting the surface liquid recycle with an anaerobic concentrated sludge. Such a system is compared with the system operating according to the present invention and the ultrafine stripping zone, the depleted phosphate, which is characterized by the stripping of the sludge from the upper liquid of the stripping zone. The calculations are based on experimentally determined sludge sedimentation characteristics and on the following process conditions: the input velocity of the waste water is about ten million gallons per day (37.8 million liters / day), the phosphate concentration in the incoming waste water is 8.5 mg / l and phosphate concentration in the final purified effluent 1.0 mg / l, the ratio of the volumetric rate of the upper liquid flow in the stripper to the flow rate of the incoming waste-water is 0.15, the ratio, the volumetric flow rate of the contact or stripping medium to the volume velocity and the upper stream of the stripping zone at 1.0; The total depth of the stripping zone is 364.0 cm formed by a layer of depth of 243 cm and a free liquid of 121 cm deep. The results of the comparative calculations are presented in Table. 3 for various process parameters, including the ratio of the space velocity of the phosphate-rich recirculating sludge to the bulk velocity of the wastewater, the concentration of suspended solids in the sludge enriched with phosphate, and the volumetric rate of the recirculating sludge enriched. phosphate gom. Results shown in Table. 3 show that the proposed system (the results under the heading have a significantly smaller cross-sectional area of the stripping zone than the known system (results under heading 1) with normal operation conditions. So, for example, with respect to the flow rate of recirculating sludge enriched in phosphate, to a volume flow rate of the incoming wastewater of 0.35, the cross-sectional area of the stripping zone in the proposed system is about 49% of the corresponding value for the known system. is the fact that the cross-sectional area of a known system is based on the spatially controlling concentration function of the stripping zone. Concentration is necessary for the known system and it is associated with separation, compaction and dewatering of the sludge fed into the clarifier to form a floating liquid in the upper part Stripping zone. Elimination to (centered function in the zone of phosphate stripping according to the invention, which is achieved in: limited special intervals the residence time of the sediment, the level of suspended solids in the stripping medium, and the ratio of the volumetric velocities of the phosphate-rich stripping medium, which are established earlier, significantly reduces the total size of the phosphate stripper zone relative to the phosphate stripper zone intended for concentration and, thus, allows significantly reduce the capital costs of equipment for the process system compared to known concentration systems. Example 4. Raw wastewater (about 45,400,000 l / day) containing about 270 parts per million (ppm) solids and 9 ppm of phosphate is passed through conventional sifting and removing devices and through a primary brightener for separation by sedimentation to obtain a primary effluent . The primary effluent is mixed with an activated phosphate bed with a reduced phosphate content of about 6,800,000 liters, which contains about 30 ppm of soluble phosphate, and air in the aeration zone and aerate it at a rate of 1.2 feet of air per gallon of waste water C0f9) in . b. The mixed liquid leaving the aeration zone is fed to the secondary settling tank. The clarified liquid, which contains almost no phosphate, is outputted in eff / foment, resulting after chlorination with a norm of the order of 45.4,000,000 l / day. The precipitated mixture of phosphate-rich sludge is discharged from a secondary settling tank at a rate of 6,800,000 l / day. Part of this sludge is fed to waste sludge, and the remainder is fed to an anaerobic phosphate steamer, which is maintained under anaerobic conditions with a residence time of 6 hours, equal to 6 hours. The conditions in the steamer cause the release of a significant amount of intercellular phosphate by the microorganisms. . A smaller part (6.800.000 l / day) of virtually no phosphate-containing effluent is discharged from the secondary sedimentation tank and removed, after which it is introduced into the lower section of the stripping zone so that it moves upward through the settled solids, due to then, the phosphate separated from the precipitated solids from the sludge is transferred to the liquid flowing upwards to form a phosphate-rich liquid in the upper part of the stripping zone. Low phosphate sludge is removed from the bottom

a phosphate steamer with a rate of 6,800,000 l / day and a phosphate-rich supernatant containing 50-60 ppm of soluble phosphate (6,800,000 l / day) are removed from the steamer and fed to a chemical precipitation tank, where lime is added and mixed with the formation of phosphate precipitate. The precipitated phosphate is determined and discarded. In the aeration zone, soluble phosphate co-injected with the recycled phosphate sludge is consumed by microorganisms j npHcyT sludge together x; phosphate contained in the incoming wastewater.

Table.

1, - .- m- - - H

Volume of speed

inlet flow, g / min 12.0

The volumetric rate of recirculating sludge enriched in phosphate (sludge from the secondary settling zone fed to the steamer, g / min

The speed of the bottom stream of the stripping zone, g / min

1.4

Top flow rate of the steam zone, g / min

Concentration of suspended solids of mixed liquid in the aeration zone, mg / l

ten

15

ten

3.3

3.0

3.0

3.0

2.8

1.2

1.5

1.7

1.8

4815

4400

4060

Yu:

Suspended volatile solids concentration in aeration zone, mg / l2454

Stay time

in the stripping zone, hours 4.8

Phosphate concentration in contacting sludge or in stripping medium, mg / l

Concentration of suspended solids in contacting sludge or in stripping medium

mg / l

The ratio of the volumetric flow rate of the contact or stripping medium to the volumetric rate of the upper flow of the stripping zone

The concentration of biological contaminants in the input stream, mg / l

Concentration of biological contaminants in effluent, mg / l

sixteen

The phosphate concentration in the feed stream.

Measured as total phosphate

Continued table. one

I; :: I: T 4 I 5

3597

3300

3160

5.4

6.3

9.8

0.8

11.3

ten

49

o; 88

2.0

1.7

120

96

18

Bulk flow rate, g / min

The volumetric rate of the recirculating flow of the sludge collected by phosphate (sludge from the secondary settling zone fed to the steamer), g / min

The speed of the lower flow of the stripping zone, g / min

The speed of the upper stream of the stripping zone, g / min

The concentration of suspended solids of the mixed liquid in the aeration zone, mg / l volatile

Concentration of suspended solids of mixed liquid in the aeration zone, mg / l

Time stay in steaming

zone, p8,2

Phosphate concentration in contact sludge or stripping medium, mg / l

Suspended solids concentration in contact sludge or in stripping medium, mg / l

The ratio of the volume velocity of the contact OR of the stripping medium to the bulk velocity of the upper stream of the stripping zone

The concentration of biological contaminants in the input stream, mg / l

Concentration of biological contaminants in effluent, mg / l

table 2

16.7

18.4

4.2 3.2 3.8

3749

1290

2790

1055

3.5

10.3

175

40

7940

o; 7

0.73

129

176

22 iiii; iiii; ii: Lii Biological concentration of phosphate in the input stream, mg / l9.6 Phosphate concentration in effluent, mg / l.6.2 Percent of total phosphate removal,% 35.4 Phosphate concentration in the bottom stream zones, mg / l 279 Phosphate concentration in the upper stream of the stripping zone, mg / l 15.0 -------- cdc measured total phosphate content Process conditions

The ratio of the volume rate of recirculating sludge enriched in phosphate (sludge from the secondary settling zone fed to the steamer / to the volume velocity of the incoming waste water

Suspended solids concentration in sludge enriched in phosphate, mg / l

The volumetric rate of recirculating sludge enriched in phosphate (sludge from the secondary settling zone fed to the steamer, million, l / day Method,

Bulk bottom flow rate ½ ml / day

The concentration of suspended solids in the bottom stream of steamers, mg / l. -....

0.35

0.4

0.3

18,700

21,200 20; 000

3.0

4.0

3.5

1.5

2.5

2.0

42,400 35) 000

29,900. , one . characterized by contacting anaerobic sludge in recirculated floating liquid Continued table. 2 10.3 81.5 603 29.8 Table 3 „| Example; j..J.Il.

Continued table. 3

Claims (1)

Claim A method of treating wastewater containing phosphate by displacing it with an oxygen-containing gas and activated sludge in the aeration zone with the formation of phosphate-rich sludge and separating it from a liquid with a low phosphate content, followed by its supply to the stripping zone while maintaining the main part of the sludge under anaerobic conditions withdrawal of phosphate-enriched liquid from the upper section of the stripping aeon, and sludge with a reduced phosphate content from the lower section of the stripping eon and supplying the specified sludge to the aeration aeon, which is characterized by In order to increase the degree of purification and reduce its time, phosphate-enriched sludge is kept in the evaporation zone for 2-10 hours when wastewater with a low phosphate content and less than 200 mg / L suspended solids is fed into the lower section of the stripping zone to move upward through part of the settled solid particles in the upper zone of the stripping column when the ratio of the volumetric rate of wastewater supplied to the lower part of the stripping eon) to the volumetric rate enriched in phosphate? liquid removed from the upper zone of stripping of phosphate in the range of 0.7-2.0.