CN104724805A - Polymeric silicic acid and polymeric titanium chloride inorganic polymer composite flocculant (PTSC) and preparation method and application thereof - Google Patents

Polymeric silicic acid and polymeric titanium chloride inorganic polymer composite flocculant (PTSC) and preparation method and application thereof Download PDF

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CN104724805A
CN104724805A CN201510135782.4A CN201510135782A CN104724805A CN 104724805 A CN104724805 A CN 104724805A CN 201510135782 A CN201510135782 A CN 201510135782A CN 104724805 A CN104724805 A CN 104724805A
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titanium tetrachloride
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inorganic polymer
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CN104724805B (en
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高宝玉
黄鑫
岳钦艳
王燕
李倩
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Shandong University
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/52Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities
    • C02F1/5236Treatment of water, waste water, or sewage by flocculation or precipitation of suspended impurities using inorganic agents

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Abstract

The invention relates to a polymeric silicic acid and polymeric titanium chloride inorganic polymer composite flocculant (PTSC) and a preparation method and application thereof. The polymeric silicic acid and polymeric titanium chloride inorganic polymer composite flocculant is prepared in the presence of chloridion. With titanium tetrachloride and sodium silicate as raw materials, sodium hydroxide is introduced into a titanium tetrachloride solution to prepare a polymeric titanium tetrachloride solution, and the polymeric titanium tetrachloride solution is mixed with polymeric silicic acid to obtain the polymeric silicic acid and polymeric titanium chloride inorganic polymer composite flocculant. Titanium tetrachloride is used as the raw material, and chloridion is introduced in the preparation process, so that the polymeric silicic acid and polymeric titanium chloride inorganic polymer composite flocculant has the advantages that excessive sulfate ions are avoided, product hydrolysis is avoided, the product stability is improved under higher titanium ion concentration, the removal rates of turbidity and organic matters at the same dosage are higher, the drug stability is obviously reinforced, the adsorption bridging ability on colloidal substances is strong, the flocculation effect is good, the application range is wide, and the pH value of the discharged water is close to be neutral to facilitate subsequent treatment.

Description

Polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant and preparation method thereof and application
Technical field
The present invention relates to polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant (PTSC) and preparation method thereof and application, belong to environment and technical field of chemistry.
Background technology
Coagulation-flocculent precipitation is simple to operate because of it, economical and efficient, becomes treatment process conventional in current water and wastewater treatment.Coagulating agent (flocculation agent) is again the important factor determining coagulation effect.Coagulating agent conventional at present mainly contains inorganic coagulant, organic coagulants, inorganic-organic polymer compound/compounding coagulation agent etc.Making a general survey of the developing direction of coagulating agent, is by low molecule to polymer substantially, by single type to compound development.At present, a kind of new polymer the superpolymer mostly coagulant newly developed is to carry out copolymerization by low molecule inorganic-organic thing and generates.This coagulating agent had both had charge neutrality and electrostatic double layer compressive action, had again the adsorption bridging effect that long-chain macromolecule is strong.
What present stage research was more is polysilicate, comprises polymeric aluminum sulfate silicate (PASS), ferric sulfate of polymerized silica and polymeric aluminum sulfate silicate iron.This kind of coagulating agent can utilize activated silicic acid negatively charged ion to increase the stability of polymeric aluminum molysite, can keep respective premium properties simultaneously, enhance adsorption bridging effect, be easy to form highdensity flco.Apply this kind of coagulating agent, chemical feeding quantity is low, and settling of floccus is rapid, and coagulation effect is good, has a clear superiority in organic in process low temperature, low-cloudy water, decolouring, removal water body.
Recent study finds, titanium salt is used as coagulating agent effectively can remove turbidity in water and organic pollutant, but because of its very easily hydrolysising titanium salt, has good screen cloth volume and sweep and adsorption bridging effect, when processing low temperature and low turbidity water, relative aluminium salt molysite has good coagulation effect.In addition, the floc particle that titanium salt produces is large, and settling velocity is obviously better than traditional coagulating agent.After titanium salt coagulation, gained mud can have the titanic oxide material that widespread use is worth after high-temperature calcination, and can solve that a large amount of mud produced in coagulation process bank up cannot handling problems, reaches the double effects of purification of water quality and mud reuse.And research in recent years finds, the relative titanium sulfate of titanium tetrachloride, the coagulation effect obtained under identical dosage is better.But the acidity of titanium solution own is comparatively strong, discharges a large amount of H in hydrolytic process +, after causing coagulation, water outlet pH obviously declines, and has a strong impact on further process and the later use of water outlet.And titanium salt is very easily hydrolyzed, when concentration is lower, period of storage is shorter.
Summary of the invention
For the deficiencies in the prior art, the invention provides a kind of polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant (PTSC) and preparation method thereof and application.
Explanation of nouns:
Basicity: the mol ratio of hydroxyl and metal ion in compound, generally represents with symbol B.
Technical scheme of the present invention is as follows:
A kind of polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant, obtained under chlorion existence condition, this composite flocculation agent is 0.48% ~ 0.72% (with SiO by concentration 2meter) polymerization of silicic acid solution and concentration be 15%-25% (wt) (in Ti) the titanium tetrachloride solution that is polymerized according to the mol ratio of Si:Ti is: the ratio of 0.02 ~ 0.1:1 mixes and obtains, the polymeric silicicacid polymerization titanium chloride Composite Inorganic Polymer Flocculants outward appearance of gained is colourless transparent solution, mass concentration is 10%-20% (wt), density is 1.10 ~ 1.54mg/L, and basicity (B) is 0.3 ~ 2.0.
The preparation method of above-mentioned polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants, prepares, comprises step as follows under chlorion existence condition:
(1) be that dropwise to join concentration be in the dilute hydrochloric acid of 0.5 ~ 1mol for the sodium silicate solution of 18 ~ 37wt% by mass concentration, control the pH < 2 of solution in whole reaction process, the final pH of regulator solution is 1.5, leaves standstill 2 ~ 3h, obtains polymerization of silicic acid solution;
(2) titanium tetrachloride solution of certain volume is measured, under Keep agitation condition, thin up is 80 ~ 100g/L to mass concentration, then the NaOH solution that concentration is 10 ~ 20wt% is dropwise added, regulate basicity (B) to 0.3 ~ 2.0, after dropwising, Keep agitation 1 ~ 2h, to solution water white transparency, obtains polymerization titanium tetrachloride solution;
(3) polymerization of silicic acid solution getting a certain amount of step (1) gained adds in the polymerization titanium tetrachloride solution of step (2) gained, in adition process, the mol ratio of control Si:Ti is 0.02 ~ 0.1:1, Keep agitation 2 ~ 3h, obtains polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants.
The present invention is preferred, and in step (1), the concentration of polymerization of silicic acid solution is 0.08 ~ 0.12mol/L.
The present invention is preferred, and the purity of titanium tetrachloride solution is 99.9%.
The present invention is preferred, and in step (2), the concentration of polyaluminium titanium solution is 80 ~ 90g/L, and basicity (B) is 0.5 ~ 1.0.
The present invention is preferred, and in step (2), the concentration of polyaluminium titanium solution is 85 ~ 90g/L, and basicity (B) is 0.5.
The present invention is preferred, the drop rate preferably 0.25 ~ 0.35ml/min of NaOH solution.
The present invention is preferred, and the mol ratio of the Si:Ti in step (3) is 0.07:1.
Raw material titanium tetrachloride of the present invention, water glass, sodium hydroxide are commercially available prod.
Polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant outward appearance prepared by the present invention is colourless transparent solution, and mass concentration is 80 ~ 100g/L, and density is 1.19235g/L.
The application of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants of the present invention, as a kind of High-efficient Water treatment agent, is applied to feedwater, wastewater treatment, the fields such as oil production, papermaking, mining, textile printing and dyeing, daily-use chemical industry.
The water treatment agent of water supply, wastewater treatment, described polymeric silicicacid is polymerized titanium tetrachloride Composite Inorganic Polymer Flocculants dosage generally at 12 ~ 38mg/L, preferred dosage 24 ~ 34mg/L.In water supply, wastewater treatment, it is 4 ~ 9 that polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants is suitable for pH value, and preferable ph is 5 ~ 7.
Polymeric silicicacid that the present invention obtains polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants titanium ion concentration is higher, under identical dosage to turbidity and organic clearance all higher, and stability of drug products obviously strengthens.Having of sulfate ion itself increases poly-effect, but excessive sulfate ion also can cause certain side effect.When chlorion and sulfate ion ratio are 4 to 1, the stability of medicine will be made to become very poor.And titanium ion hydrolysis itself is comparatively rapid, (especially a large amount of sulfate ions, as Ti in titanium sulfate in the introducing of sulfate radical 4+/ SO 4 2-=2:1) stability of coagulating agent will certainly be caused seriously to reduce.The present invention adopts titanium tetrachloride as raw material, avoids too much introducing sulfate ion, and the stability that effectively prevent medicine reduces.
Polymeric silicicacid is introduced titanium tetrachloride and is formed the molecular weight that compound coagulant can improve coagulating agent by the present invention, strengthens its adsorption bridging ability, also can improve water outlet pH to a certain extent simultaneously, and strengthen the stability of titanium salt.Present strongly-acid to cause flocculating lower and comparatively this shortcoming of facile hydrolysis of the pH of water outlet to overcome titanium tetrachloride itself, the present invention adopts drips alkaline process, make the prehydrolysis of titanium tetrachloride titanium, thus alleviate its strong hydrolytic action to a certain extent, and add electronegative polysilicon acid on this basis and limit its hydrolysis rate, strengthen its period of storage, also can improve its adsorption bridging ability simultaneously, the basis of improving flocculating effect also improves water outlet pH value and the period of storage of the medicine increased.
Polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant of the present invention compared with prior art has following excellent results:
1, polymeric silicicacid polyaluminium titanium Ti-inorganic polymer composite flocculant of the present invention, for raw material with titanium tetrachloride, water glass, adopt the method preparation be incorporated in titanium tetrachloride solution by sodium hydroxide to be polymerized titanium tetrachloride solution, then polymerization titanium tetrachloride solution and polymeric silicicacid are mixed.The present invention adopts titanium tetrachloride as raw material, chlorion is introduced in preparation process, avoid too much sulfate ion, avoid product hydrolysis, the stability of product is improve under higher titanium ion concentration, under identical dosage to turbidity and organic clearance all higher, and stability of drug products obviously strengthens, strong to the adsorption bridging ability of colloidalmaterial, flocculating effect good, applied widely, water outlet pH facilitates the advantages such as subsequent disposal close to neutrality.
2, polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant of the present invention is compared with polyaluminum sulfate titanium flocculation agent, add polymeric silicicacid, polymerization titanium tetrachloride and polysilicon acid there occurs to interact and form Si-O-Ti key, make composite flocculation agent have good bridging and netting and complexing action to pollutent, flocculating effect is better.
3, polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant of the present invention is compared with polymeric silicicacid-titanium sulfate flocculation agent, alkalize owing to utilizing titanium tetrachloride, comparatively to compare coagulation effect better for titanium sulfate, and due to drug concentration large compared with titanium sulfate product concentration, be hydrolyzed relatively slow, medicine period of storage is longer, and the basis of improving flocculating effect also improves the period of storage of medicine, significant to flocculation treatment.
Embodiment
Below in conjunction with embodiment and application examples, the present invention will be further described, but be not limited thereto.
Embodiment
(1) 13.6692g Na is taken 2siO 39H 2o solid is dissolved in about 30mL water, it is dropwise joined in the dilute hydrochloric acid of 0.5mol concentration, regulates pH to be less than 2 all the time with the dilute hydrochloric acid of 0.5mol/L, and to control final pH be 1.5, is settled to 250mL, obtains 0.192375mol/L (with SiO after ageing 2h 2meter) polymerization of silicic acid solution;
(2) titanium tetrachloride solution of four part 20% is measured, every part of 20mL, be placed in magnetic stirring apparatus respectively to stir, dropwise add with the drop rate of 0.3ml/min NaOH solution to the basicity that concentration is 10wt% simultaneously and be respectively 0.5,1.0,1.5,0.0 (for contrast), after dropwising, Keep agitation 1h, to solution water white transparency, obtains polymerization titanium tetrachloride solution;
(3) the polymerization titanium tetrachloride solution of different basicity is divided into five parts respectively, according to Si/Ti mol ratio be 0.1,0.07,0.05,0.02,0.0 (for contrast) join obtained polymerization of silicic acid solution respectively after stir 2h to solution water white transparency, the polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant obtaining the different Si/Ti mol ratio of different basicity (is designated as PTSC respectively m0.1, PTSC m0.07, PTSC m0.05, PTSC m0.02, PTC.
Application example
With polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant process xanthohumic acid-Kaolin water sample that embodiment is obtained, and analysis processing result.
Experiment water sample compound method is as follows: take 1g humic acid and 0.4g sodium hydroxide, be in harmonious proportion with a small amount of deionized water, after magnetic agitation 0.5h, constant volume is to 1L, is mixed with 1gL -1simulated water sample stock solution.Take 1g kaolin, add appropriate amount of deionized water and dissolve, pour into after magnetic agitation 0.5h in the graduated cylinder of 1L and be settled to 1L, after leaving standstill 0.5h, draw 500 milliliters, upper strata and be experiment aqueous suspension ofkaolin used.During flocculating experiment, be in harmonious proportion with tap water and be made into concentration for 10mgL – 1xanthohumic acid simulated water sample, utilizes aqueous suspension ofkaolin to regulate raw water turbidity to be 15.0 ± 0.50NTU, obtains xanthohumic acid-Kaolin water sample.
Humic acid acid-Kaolin water sample index is: raw water turbidity is 15.0 ± 0.50NTU, and the absorbancy under wavelength is 254nm is 0.395 ~ 0.425, and dissolved organic carbon DOC is 5.000 ± 0.2mg/L.Flocculating effect is with residual turbidity, UV 254represent with the clearance (%) of DOC and water outlet pH value.
Application example one
To be 0.5, Si/Ti mol ratio by the basicity of gained in embodiment be 0.1,0.07,0.05,0.02 polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant be applied to the process of humic acid-Kaolin water sample.
Result is as shown in table 1 below:
Table 1 basicity is the treatment effect (flocculant dosage 28m-Ti/L) of polymeric silicicacid titanium chloride Composite Inorganic Polymer Flocculants to xanthohumic acid-Kaolin water sample of the different Si/Ti mol ratios of 0.5
From above result, the residual turbidity of water outlet along with the increase first increases and then decreases of Si/Ti ratio, at Si/Ti than being reach minimum when 0.07.For UV 254clearance, its variation tendency is also the increase first increases and then decreases along with Si/Ti mol ratio, and PTSSm removal effect when Si/Ti mol ratio is 0.07 reaches best, is 86.90%.PTSCm DOC clearance also show the trend of same first increases and then decreases, reaches maximum when Si/Ti mol ratio is 0.07.In addition, Si/Ti mol ratio also has considerable influence to water outlet pH, and along with the increase water outlet pH adding silicon amount increases gradually, and close to neutral, this will be conducive to the subsequent disposal of water outlet.As can be seen here, Si/Ti mol ratio has material impact to flocculating effect, and certain Si/Ti mol ratio can optimize flocculating effect.
Application example two
The basicity of gained in embodiment is respectively 0.5,1.0,1.5, Si/Ti mol ratios be 0.07 polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant be applied in the process of xanthohumic acid-Kaolin water sample.Research basicity is on the impact of the flocculation treatment effect of polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant, and simultaneously with basicity=0.0, Si/Ti compares than the flocculation treatment effect being 0.07, the results are shown in following table 2.
Table 2Si/Ti mol ratio is the different basicities (0.5 of 0.07,1.0,1.5) composite algorithm polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant is to the treatment effect (flocculant dosage: 28mg-Ti/L) of xanthohumic acid-Kaolin water sample
As can be seen from above-mentioned result, within the scope of the basicity of 0.5 ~ 1.5, along with the rising of basicity, the residual turbidity of water outlet raises gradually, and UV 254the clearance of clearance and DOC also reduces gradually; When basicity reaches 1.5, flocculating effect is the poorest, and the clearance of DOC, close to 50%, reaches 55.2%.Titanium salt is suitable for hydrolysis, and basicity is higher can accelerate its hydrolysis, is unfavorable for the long-term deposit of flocculation agent.Lower basicity can reach good flocculating effect, PTSS during B=0.5 muV 254be respectively 86.9% and 65.1% with DOC clearance, but when basicity=0.0, residual turbidity than slightly high during B=0.5, UV 254the clearance of clearance and DOC is also than lower slightly during B=0.5, and as can be seen here, basicity is to the coagulation effect important of flocculation agent, and certain basicity can optimize flocculating effect.
Application example three
By basicity=0.5 of gained in embodiment, Si/Ti mol ratio be 0.07 polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant be applied to process different pH value obtain xanthohumic acid-Kaolin water sample.Choosing pH scope is 4 ~ 9, and flocculant dosage is 28mg/L, flocculating effect with residual turbidity, UV 254be index with DOC clearance and water outlet pH, result is as shown in table 3 below.
Under table 3 condition of different pH, composite algorithm polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant is to the treatment effect (flocculant dosage: 28mg-Ti/L) of xanthohumic acid-Kaolin water sample
As can be seen from the result of upper table, polymeric silicicacid polymer-inorganic polymer composite flocculant is when processing humic acid-Kaolin water sample, and flocculating effect first increases rear reduction along with the rising of pH, and when pH=5, flocculating effect reaches good.And when pH=9, delivery turbidity is minimum, the turbidity of the medicament of two kinds of method synthesis is respectively 1.71NTU and 2.02NTU, when pH=5, and UV 254clearance reach the highest, UV 254clearance be respectively 90.92% and 90.97%, DOC clearance be respectively 59.37% and 65.59%.In the basic conditions, composite algorithm flocculating effect is poor.From the above results, the flocculating effect of water outlet pH to polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant has material impact.
Reference examples 1
A preparation method for Polymeric silicic acid-polyferric sulfate titanium inorganic macromolecular composite flocculant, step is as follows:
(1) 13.6692g Na is taken 2siO 39H 2o solid is dissolved in about 30mL water, it is dropwise joined in the dilute hydrochloric acid of 0.5mol concentration, regulates pH to be less than 2 all the time with the dilute hydrochloric acid of 0.5mol/L, and to control final pH be 1.5, is settled to 250mL, obtains 0.192375mol/L (with SiO after ageing 2h 2meter) polymerization of silicic acid solution;
(2) titanium sulfate solid 12.5g is taken, be dissolved in 150ml water and stir until solution is water white transparency, sodium hydroxide solution that concentration is 10wt% is dropwise added to basicity for 0.5 with the drop rate of 0.3ml/min, after dropwising, Keep agitation 1h, to solution water white transparency, obtains polyaluminum sulfate titanium solution;
(3) according to Si/Ti mol ratio be 0.07 join obtained polymerization of silicic acid solution after stir 2h to solution water white transparency, obtain Polymeric silicic acid-polyferric sulfate titanium inorganic macromolecular composite flocculant.
Application example four
Embodiment and reference examples 1 composite flocculation agent are applied to the process of humic acid-Kaolin water sample, the basicity of flocculation agent is 0.5, Si/Ti mol ratio and is 0.07, flocculant dosage: 28mg-Ti/L.
Result is as shown in table 4 below:
The coagulation effect of implementation column and reference examples under the identical dosage of table 4
From upper table 4 result, (28mg/L under identical dosage, in titanium), no matter be delivery turbidity or organic clearance, polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant of the present invention is all higher than reference examples, the residual turbidity of embodiment and reference examples is respectively 1.64 and 1.93, the clearance of UV254 and DOC is 89.6% and 65.1%, 77.35% and 53.6%, water outlet pH after coagulation is substantially identical, be respectively 7.22 and 7.23, in addition, from the zeta current potential result of water outlet, the charge neutrality ability of the embodiment of the present invention is slightly better than reference examples, the present invention adopts titanium tetrachloride as raw material, chlorion is introduced in preparation process, avoid too much sulfate ion, avoid product hydrolysis, the stability of product is improve under higher titanium ion concentration, under identical dosage to turbidity and organic clearance all higher, by the storage time, the polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant storage time of the present invention is longer, performance is more stable, the present invention adopts titanium tetrachloride as raw material, chlorion is introduced in preparation process, avoid too much sulfate ion, avoid product hydrolysis.

Claims (9)

1. a polymeric silicicacid polyaluminium Ti-inorganic polymer composite flocculant, is characterized in that, obtained under chlorion existence condition, and this composite flocculation agent is 0.48% ~ 0.72% (with SiO by concentration 2meter) polymerization of silicic acid solution and concentration be 15%-25% (wt) (in Ti) the titanium tetrachloride solution that is polymerized according to the mol ratio of Si:Ti is: the ratio of 0.02 ~ 0.1:1 mixes and obtains, the polymeric silicicacid polymerization titanium chloride Composite Inorganic Polymer Flocculants outward appearance of gained is colourless transparent solution, mass concentration is 10%-20% (wt), density is 1.10 ~ 1.54mg/L, and basicity (B) is 0.3 ~ 2.0.
2. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, prepares, comprises step as follows under chlorion existence condition:
(1) be that dropwise to join concentration be in the dilute hydrochloric acid of 0.5 ~ 1mol for the sodium silicate solution of 18 ~ 37wt% by mass concentration, control the pH < 2 of solution in whole reaction process, the final pH of regulator solution is 1.5, leaves standstill 2 ~ 3h, obtains polymerization of silicic acid solution;
(2) titanium tetrachloride solution of certain volume is measured, under Keep agitation condition, thin up is 80 ~ 100g/L to mass concentration, then the NaOH solution that concentration is 10 ~ 20wt% is dropwise added, regulate basicity (B) to 0.3 ~ 2.0, after dropwising, Keep agitation 1 ~ 2h, to solution water white transparency, obtains polymerization titanium tetrachloride solution;
(3) polymerization of silicic acid solution getting a certain amount of step (1) gained adds in the polymerization titanium tetrachloride solution of step (2) gained, in adition process, the mol ratio of control Si:Ti is 0.02 ~ 0.1:1, Keep agitation 2 ~ 3h, obtains polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants.
3. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, it is characterized in that, in step (1), the concentration of polymerization of silicic acid solution is 0.08 ~ 0.12mol/L.
4. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, it is characterized in that, the purity of titanium tetrachloride solution is 99.9%.
5. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, it is characterized in that, in step (2), the concentration of polyaluminium titanium solution is 80 ~ 90g/L, and basicity (B) is 0.5 ~ 1.0.
6. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, it is characterized in that, in step (2), the concentration of polyaluminium titanium solution is 85 ~ 90g/L, and basicity (B) is 0.5.
7. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, is characterized in that, the drop rate preferably 0.25 ~ 0.35ml/min of NaOH solution.
8. the preparation method of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, it is characterized in that, the mol ratio of the Si:Ti in step (3) is 0.07:1.
9. the application of polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants according to claim 1, the water treatment agent of water supply, wastewater treatment, described polymeric silicicacid polymerization titanium tetrachloride Composite Inorganic Polymer Flocculants dosage is at 12 ~ 38mg/L, preferred dosage 24 ~ 34mg/L, pH value is 4 ~ 9, and preferable ph is 5 ~ 7.
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CN111977766A (en) * 2020-09-04 2020-11-24 常熟理工学院 Preparation method of aluminum-titanium-based photocatalytic coagulant, product and application thereof
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CN102976462A (en) * 2012-12-20 2013-03-20 山东大学 Polymerized titanium tetrachloride inorganic polymeric flocculant and preparation method of inorganic polymeric flocculant
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CN108128863B (en) * 2017-12-21 2019-08-09 北京工业大学 A kind of preparation method of polymeric silicicacid polyaluminium zirconium inorganic polymer flocculant
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