CN106830492B

CN106830492B - Treatment method of methoxy acrylic ester pesticide product wastewater

Info

Publication number: CN106830492B
Application number: CN201710217270.1A
Authority: CN
Inventors: 尚鸿艳; 孙敬权; 李新生; 张荣全; 庄文栋; 孙丽梅; 冯小冬
Original assignee: Limin Chemical Co ltd
Current assignee: Limin Chemical Co.,Ltd.
Priority date: 2017-04-05
Filing date: 2017-04-05
Publication date: 2021-04-20
Anticipated expiration: 2037-04-05
Also published as: CN106830492A

Abstract

The invention relates to a method for treating wastewater of strobilurin pesticide products, which comprises the following steps: collecting and filtering wastewater; adding sulfuric acid, adjusting the pH value, and converting inorganic sylvite into potassium sulfate; UV-photocatalytic oxidation is carried out, so that organic potassium salt is converted into potassium sulfate; adding potassium hydroxide, adjusting the pH value, neutralizing excessive sulfuric acid, and then adding ferric trichloride for precipitation reaction; filtering to remove flocculate; multi-effect evaporation, crystallization, centrifugation and separation to obtain solid potassium sulfate, and the steam condensate and the distilled water are both reused in a workshop. Realizes the resource utilization of the wastewater, realizes zero discharge of the wastewater and has higher economic and environmental benefits.

Description

Treatment method of methoxy acrylic ester pesticide product wastewater

Technical Field

The invention relates to the technical field of wastewater treatment, in particular to a method for treating wastewater of strobilurin pesticide products.

Background

The method for producing the strobilurin pesticide products such as pyraclostrobin, azoxystrobin, kresoxim-methyl, trifloxystrobin and the like comprises the following steps: raw pesticide, potassium methyl sulfate, potassium carbonate and potassium bicarbonate mixed salt, CODcr 30000-40000 mg/l.

For high-salinity wastewater, the treatment process commonly adopted by the current production enterprises is as follows: the first step is as follows: press filtering and recovering the product; step two, evaporation desalting: the CODcr of the distilled water is 5000 and 10000mg/l, the distilled water is discharged after reaching the standard after being further processed, and the mixed salt is entrusted to be disposed as dangerous waste.

The traditional treatment process has the following problems:

1) because the CODcr concentration of the wastewater is high, the mixed salt obtained by direct evaporation without pretreatment can only be treated as hazardous waste, thereby greatly increasing the treatment cost and wasting useful resources.

2) The distilled water still contains higher organic matters, can be discharged after reaching the standard after being further treated, has higher treatment cost and does not generate economic benefit.

Disclosure of Invention

In order to solve the defects in the prior art, the invention aims to provide a method for treating wastewater of strobilurin pesticide products, so that the resource utilization of high-concentration high-salt content in the wastewater is realized, the produced potassium sulfate is sold as a byproduct, steam condensate water and distilled water are recycled in a workshop, tail gas is absorbed by alkali and then is discharged up to the standard, no secondary pollution is generated, and good economic and environmental benefits are achieved.

In order to realize the aim, the invention provides a method for treating waste water of strobilurin pesticide products, which comprises the following steps:

1) collecting and filtering wastewater;

2) adding sulfuric acid, adjusting the pH value, and converting inorganic sylvite into potassium sulfate;

3) UV-photocatalytic oxidation is carried out, so that organic potassium salt is converted into potassium sulfate;

4) adding potassium hydroxide, adjusting the pH value, neutralizing excessive sulfuric acid, and then adding ferric trichloride to perform a flocculation precipitation reaction;

5) filtering to remove flocculate;

6) multi-effect evaporation, crystallization, centrifugation and separation to obtain solid potassium sulfate, and the steam condensate and the distilled water are both reused in a workshop.

Further, the filtering step in the step 1) adopts a duplex filter.

Further, the pH value is adjusted to 2.5-3.0 in the step 2).

Further, the inorganic potassium salt in the step 2) is potassium carbonate and potassium bicarbonate, and the reaction formula is as follows:

K₂CO₃+H₂SO₄→K₂SO₄+H₂O+CO₂↑

2KHCO₃+H₂SO₄→K₂SO₄+2H₂O+2CO₂↑。

further, the organic potassium salt in the step 3) is potassium methyl sulfate, and the reaction formula is as follows:

R-H+HO^·→R^·+H₂O

2K(CH₃)SO₄+3O₂→K₂SO₄+2H₂O+2CO₂↑+H₂SO₄。

further, the pH value is adjusted to 6.0-7.0 in the step 4).

Further, the reaction formula in the step 4) is as follows:

H₂SO₄+2KOH→K₂SO₄+2H₂O

3KOH+FeCl₃→Fe(OH)₃↓+3KCl。

further, the flocculate in the step 5) comprises ferric hydroxide and a small part of flocculateable small molecular organic matters.

Further, the gas generated by the reaction in the step 2) and the step 3) and the gas generated in the evaporation process in the step 6) are subjected to alkali absorption treatment.

Furthermore, the alkali absorption is carried out by adopting a two-stage spray tower, and the alkali in the alkali absorption is sodium hydroxide aqueous solution or sodium carbonate aqueous solution.

Compared with the prior art, the invention has the following advantages:

1) the duplex filter is adopted to replace the traditional filter pressing in the product recovery process, the operation is simpler and more convenient, and the field environment is greatly improved.

2) The acid adjustment of the wastewater converts the mixed salt of potassium carbonate and potassium bicarbonate into single potassium sulfate, and the UV-photocatalytic oxidation technology is utilized to convert the methyl potassium sulfate into potassium sulfate, so that the conversion from the mixed salt to the single salt in the wastewater is realized, and the mixed salt originally treated as hazardous waste can be recycled.

3) The whole process realizes zero discharge of wastewater and the aim of circular economy: the potassium salt in the wastewater is recovered and sold as a byproduct, the mother liquor is steamed, and the steam condensate and the distilled water are reused in a workshop, so that the water resource is greatly saved.

In conclusion, the invention provides a method for treating wastewater of strobilurin pesticide products, which realizes the resource utilization of high-concentration high-salt content in the wastewater, has good wastewater treatment effect, and effectively solves the defects of high cost, low efficiency and large amount of hazardous wastes in the prior treatment technology. The purpose of recycling the waste water is realized, energy and water resources are saved, and economic and environmental benefits are unified.

Drawings

FIG. 1 is a process flow chart of the wastewater treatment of the strobilurin pesticide product of the present invention.

Detailed Description

In order to better explain the present invention, the following description is given with reference to the accompanying drawings and the specific embodiments.

As shown in figure 1, the wastewater contains 1.3-1.5% of strobilurin pesticide product, 7.2-7.5% of potassium methyl sulfate, 4.8-5.0% of potassium bicarbonate and 1.4-1.6% of potassium carbonate.

Example 1

Step one, waste water is collected and is filtered and retrieve the product: 38 tons of wastewater is produced in a workshop every day, the wastewater enters a wastewater collection tank, the bottom of the tank is conical, a duplex filter is arranged at the outlet of a wastewater pump and used for filtering and recovering products, 0.5 ton of the products can be recovered every day, the duplex filter is provided with pressure interlocking control, when one pressure is high, an alarm is given and the other is switched, the phenomenon that the treatment flow is continuous due to blockage is avoided, 37.5 tons of filtrate is produced every day, and the wastewater enters a second step for treatment.

Step two, adjusting the pH: waste water with a particle size of 3.0m³The volume per hour is pumped into a pH adjusting tank,simultaneously adding 98% of sulfuric acid, controlling the proportion of acid and wastewater according to a mass flow meter, wherein the adding amount of the sulfuric acid is 114kg/h, automatically adjusting the pH value to 2.5, reacting potassium carbonate (45kg/h) and potassium bicarbonate (145kg/h) in the wastewater to generate potassium sulfate (178kg/h), and introducing tail gas into an alkaline washing spray tower through an air inducing system for treatment.

Step three, UV-photocatalytic oxidation: 3.2m for wastewater with pH 2.5³The volume per hour is pumped into a UV-photocatalytic oxidation process system to pretreat the wastewater, 27.5 percent hydrogen peroxide and 40 percent ferric trichloride solution are added by an automatic dosing system, the adding amount is respectively 1500ppm and 170ppm, and the organic matter is degraded into CO through the oxidation of hydroxyl free radicals₂、H₂O, micromolecular acid and methyl potassium sulfate (220kg/h) are oxidized to generate potassium sulfate (128kg/h), and tail gas is introduced into an alkaline washing spray tower through an induced air system for treatment.

Step four, adjusting the pH: the wastewater of the previous step is 3.3m³The amount per hour is pumped into a pH adjusting tank, the waste water is neutralized by 40 percent potassium hydroxide, the proportion of a potassium hydroxide solution to the waste water is controlled according to a mass flow meter, the adding amount of the 40 percent potassium hydroxide is 270kg/h, the pH of the waste water is automatically adjusted to be 6.0, simultaneously, redundant sulfuric acid (72kg/h) reacts to generate potassium sulfate (128kg/h), and the potassium sulfate reacts with trace ferric trichloride (0.025kg/h) added by a UV-photocatalytic oxidation automatic medicine feeding system to generate ferric hydroxide (0.015kg/h) and potassium chloride (0.035 kg/h).

Fifthly, filtering and removing impurities: a small portion of floc (0.025kg/h) formed by the reaction, which includes ferric hydroxide and a small amount of small molecule organic matter that can flocculate, was filtered.

Sixthly, multi-effect evaporation and centrifugal separation: the pH value of the wastewater treated in the first five steps is 6.0 and is 3.3m³The volume per hour is pumped into a multi-effect evaporation system, and the waste water contains 434kg/h K generated by the reaction₂SO₄With 0.035kg/h KCl, 0.011kg KCl is generated per ton of waste water, and K is contained in per ton of waste water₂SO₄131.5kg, KCl only accounts for 0.008 percent of the total salt content, so the produced KCl does not influence the byproduct K₂SO₄The quality of (c). Concentrating in a first, second and third effect evaporator under vacuum state to obtain supersaturated potassium sulfate solution, crystallizing in a crystallization kettle, and centrifuging to obtain sulfuric acidPotassium (490kg/h, content > 85%) is sold as a by-product, steam condensate and distilled water (2.4 m)³/h，CODcr≤500mg/1，NH₃N is less than or equal to 30mg/l) is recycled in a workshop, and noncondensable tail gas generated in the evaporation process is introduced into an alkaline washing spray tower through an induced air system for treatment.

The alkali in the alkali washing spray tower treatment involved in the second, third and sixth steps is 2-5% sodium hydroxide aqueous solution.

Example 2

The first step is the same as example 1.

Step two, adjusting the pH: waste water with a particle size of 3.2m³The volume per hour is pumped into a pH adjusting tank, 80% waste sulfuric acid is added at the same time, the proportion of acid and waste water is controlled according to a mass flow meter, the adding volume of the sulfuric acid is 150kg/h, the pH value is automatically adjusted to be 2.8, potassium carbonate (46kg/h) and potassium bicarbonate (150kg/h) in the waste water react to generate potassium sulfate (190kg/h), and tail gas is introduced into an alkaline washing spray tower through an air inducing system for treatment.

Step three, UV-photocatalytic oxidation: 3.3m for wastewater with pH 2.8³The volume per hour is pumped into a UV-photocatalytic oxidation process system to pretreat the wastewater, 30 percent hydrogen peroxide and 35 percent ferric trichloride solution are added by an automatic dosing system, the adding amount is 1450ppm and 200ppm respectively, and the organic matter is degraded into CO through the oxidation of hydroxyl free radicals₂、H₂O, micromolecular acid and methyl potassium sulfate (223kg/h) are oxidized to generate potassium sulfate (130kg/h), and tail gas is introduced into an alkaline washing spray tower through an induced air system for treatment.

Step four, adjusting the pH: the wastewater of the previous step is 3.3m³The volume per hour is pumped into a pH adjusting tank, 38 percent potassium hydroxide is used for neutralizing wastewater, the proportion of a potassium hydroxide solution to the wastewater is controlled according to a mass flow meter, the adding volume of the 38 percent potassium hydroxide is 290kg/h, the pH of the wastewater is automatically adjusted to 6.5, simultaneously, redundant sulfuric acid (94kg/h) reacts to generate potassium sulfate (130kg/h), and the potassium sulfate reacts with trace ferric trichloride (0.026kg/h) added by a UV-photocatalytic oxidation automatic dosing system to generate ferric hydroxide (0.017kg/h) and potassium chloride (0.036 kg/h).

Fifthly, filtering and removing impurities: a small part of flocculate (0.026kg/h) produced by the reaction was filtered, the flocculate consisting of ferric hydroxide and a small amount of small organic flocculants.

Sixthly, multi-effect evaporation and centrifugal separation: the pH value of the wastewater treated in the first five steps is 6.5 and is 3.3m³The volume per hour is pumped into a multi-effect evaporation system, and the waste water contains 450kg/h K generated by reaction₂SO₄With 0.036kg/h KCl, 0.011kg of KCl is generated in each ton of wastewater, and K is contained in each ton of wastewater₂SO₄136.4kg, KCl only accounts for 0.008 percent of the total salt content, so the produced KCl does not influence the byproduct K₂SO₄The quality of (c). Concentrating in a first, second and third effect evaporator under vacuum to obtain supersaturated potassium sulfate solution, crystallizing in a crystallization kettle, centrifuging to obtain potassium sulfate (498kg/h, content greater than or equal to 85%) as byproduct, and steam-condensing water and distilled water (2.5 m)³/h，CODcr≤500mg/l，NH₃N is less than or equal to 30mg/l) is recycled in a workshop, and noncondensable tail gas generated in the evaporation process is introduced into an alkaline washing spray tower through an induced air system for treatment.

The alkali in the alkali washing spray tower treatment involved in the second, third and sixth steps is 5-15% sodium carbonate aqueous solution.

Example 3

The first step is the same as example 1.

Step two, adjusting the pH: waste water with a particle size of 3.2m³Pumping the volume/h into a pH adjusting tank, simultaneously adding 98% sulfuric acid, controlling the proportion of acid and wastewater according to a mass flow meter, wherein the adding volume of the sulfuric acid is 125kg/h, automatically adjusting the pH to 3.0, reacting potassium carbonate (48kg/h) and potassium bicarbonate (152kg/h) in the wastewater to generate potassium sulfate (193kg/h), and introducing tail gas into an alkaline washing spray tower through an air inducing system for treatment.

Step three, UV-photocatalytic oxidation: 3.3m for wastewater with pH 3.0³The volume per hour is pumped into a UV-photocatalytic oxidation process system to pretreat the wastewater, an automatic dosing system is adopted to add 30 percent hydrogen peroxide and 50 percent ferric trichloride solution, the adding amount is 1400ppm and 150ppm respectively, and the organic matter is degraded into CO through the oxidation of hydroxyl free radicals₂、H₂O, micromolecular acid and methyl potassium sulfate (225kg/h) are oxidized to generate potassium sulfate (131kg/h), and tail gas is introduced into an alkaline washing spray tower through an induced air system for treatment.

Step four, adjusting the pH: waste of last stepWater at 3.3m³The amount of potassium hydroxide is pumped into a pH adjusting tank, the waste water is neutralized by 40 percent of potassium hydroxide, the proportion of a potassium hydroxide solution to the waste water is controlled according to a mass flow meter, the adding amount of the 40 percent of potassium hydroxide is 280kg/h, the pH of the waste water is automatically adjusted to be 7.0, simultaneously, redundant sulfuric acid (74kg/h) reacts to generate potassium sulfate (131kg/h), and the potassium sulfate reacts with trace ferric trichloride (0.03kg/h) added by a UV-photocatalytic oxidation automatic medicine feeding system to generate ferric hydroxide (0.02kg/h) and potassium chloride (0.04 kg/h).

Fifthly, filtering and removing impurities: a small portion of floc (0.03kg/h) formed by the reaction, which includes ferric hydroxide and a small amount of small molecule organic matter that can flocculate, was filtered.

Sixthly, multi-effect evaporation and centrifugal separation: the pH value of the wastewater treated in the first five steps is 7.0 and is 3.3m³The amount of the waste water is pumped into a multi-effect evaporation system, and 455kg/h K generated in the reaction is contained in the waste water₂SO₄0.04kg/h KCl, 0.012kg of KCl is generated in each ton of wastewater, and each ton of wastewater contains K₂SO₄142kg, KCl only accounts for 0.008 percent of the total salt content, so the produced KCl does not influence the byproduct K₂SO₄The quality of (c). Concentrating in a first, second and third effect evaporator under vacuum to obtain supersaturated potassium sulfate solution, crystallizing in a crystallization kettle, centrifuging to obtain potassium sulfate (510kg/h, content is greater than or equal to 85%) as byproduct, and steam condensate and distilled water (2.5 m)³/h，CODcr≤500mg/l，NH₃N is less than or equal to 30mg/l) is recycled in a workshop, and noncondensable tail gas generated in the evaporation process is introduced into an alkaline washing spray tower through an induced air system for treatment.

The alkali in the alkali washing spray tower treatment involved in the second, third and sixth steps is 5-10% of sodium hydroxide aqueous solution.

Example 4

Comparing the process of the present invention with the conventional treatment process, the comprehensive benefits of the process of the present invention were analyzed based on the average consumption of examples 1-3, and the results are shown in table 1.

TABLE 1 analysis of the overall benefits (in terms of ton of wastewater)

Process of treatment	Conventional treatment process	The process of the invention
			Filtration recovery of products	Filter pressing	Duplex filtration
Adjusting the pH	/	98％H₂SO₄38.4kg, 19 yuan
			UV-photocatalytic oxidation	/	100 yuan
Adjusting the pH	/	40% KOH 83.4kg, -83 yuan
			Filtering to remove impurities	/	/
Multiple effect evaporation and centrifugal separation	-180 units	-150 yuan
			Treatment of distilled water	100 yuan	Saving water 750kg, 1.7 yuan
Hazardous waste treatment/byproduct recovery	220kg of dangerous waste with the power of-660 yuan	151.3kg K₂SO₄By-product, 310 Yuan
			Combined cost/benefit	-940 element	-40.3 membered

According to the analysis results obtained in the table 1, the process can save 1079.6 ten thousand yuan compared with the traditional treatment mode according to 1.2 ten thousand tons of annual treated wastewater, and the purposes of recycling the wastewater and saving energy and water resources are realized.

Although a few exemplary embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these exemplary embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

Claims

1. A method for treating waste water of strobilurin pesticide products comprises the following steps:

1) collecting waste water and filtering by adopting a duplex filter;

2) the wastewater is treated at a rate of 3.0m³Pumping the volume per hour into a pH adjusting tank, simultaneously adding 98% sulfuric acid, controlling the proportion of acid and wastewater according to a mass flow meter, wherein the adding volume of the sulfuric acid is 114kg/h, adjusting the pH to 2.5, reacting 45kg/h potassium carbonate and 145kg/h potassium bicarbonate in the wastewater to generate 178kg/h potassium sulfate, and introducing tail gas into an alkaline washing spray tower through an induced air system for treatment;

3) the wastewater with pH 2.5 generated in step 2) was treated at 3.2m³Pumping the wastewater into a UV-photocatalytic oxidation process system in a volume of/h, and pretreating the wastewater; 27.5 percent of hydrogen peroxide and 40 percent of ferric trichloride solution are added by an automatic medicine adding systemThe addition amounts are 1500ppm and 170ppm respectively; degradation of organic matter to CO by oxidation of hydroxyl radicals₂、H₂O and a small molecule acid; oxidizing 220kg/h potassium methyl sulfate to generate 128kg/h potassium sulfate, and introducing tail gas into an alkaline washing spray tower through an induced air system for treatment;

4) 3.3m of wastewater generated in the step 3)³Pumping the solution into a pH adjusting tank by a volume/h, neutralizing the wastewater by 40% potassium hydroxide, and controlling the proportion of a potassium hydroxide solution to the wastewater according to a mass flow meter, wherein the adding amount of the 40% potassium hydroxide is 270 kg/h; adjusting the pH value of the wastewater to 6.0, and simultaneously reacting excessive 72kg/h of sulfuric acid to generate 128kg/h of potassium sulfate; 0.025kg/h of ferric trichloride is added into an UV-photocatalytic oxidation automatic dosing system to react to generate 0.015kg/h of ferric hydroxide and 0.035kg/h of potassium chloride;

5) filtering floc of 0.025kg/h generated by the reaction, wherein the floc comprises ferric hydroxide and flocculent micromolecule organic matter;

6) the treated wastewater with pH of 6.0 was treated at 3.3m³The volume per hour is pumped into a multi-effect evaporation system, and the waste water contains 434kg/h K generated by the reaction₂SO₄And 0.035kg/h KCl; concentrating in a first, second and third effect evaporator under vacuum state to obtain supersaturated potassium sulfate solution, crystallizing in a crystallization kettle, centrifuging to obtain 490kg/h potassium sulfate with content not less than 85%, and 2.4m³/h、CODcr≤500mg/1、NH₃The steam condensate water and the distilled water with the N less than or equal to 30mg/l are reused in a workshop; the noncondensable tail gas generated in the evaporation process is introduced into an alkaline washing spray tower through an induced air system for treatment.

2. The method for treating the waste water of the strobilurin pesticide products as claimed in claim 1, wherein the alkali washing spray tower is implemented by adopting a two-stage spray tower, and the alkali in the alkali washing spray tower is an aqueous sodium hydroxide solution or an aqueous sodium carbonate solution.