CN110054265B - Deep clean sewage treatment process - Google Patents

Abstract

The invention relates to a deep clean sewage treatment process, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment. The sewage treatment process can treat industrial sewage, has high efficiency and low cost, can continuously treat and sterilize the industrial sewage with higher pollution degree, and simultaneously ensures that the treated sewage is colorless and tasteless; the treated sewage can reach the discharge standard and has no secondary pollution.

Description

Deep clean sewage treatment process

Technical Field

The invention relates to a process for treating deep clean sewage.

Background

While the economy continues to develop nowadays, a series of problems such as the generation of industrial sewage and domestic sewage is increasing year by year, the problem of water resource shortage is increasing day by day, and the like are generated. In 1972, the first meeting of the human environment held by the united nations proposed "after the oil crisis, the next crisis was water". Especially for the large country in China, the problem of water resource shortage is more serious and is one of 13 major water-deficient countries, and the average occupied amount of water resources of each person is 1/4 of the occupied amount of people all over the world. The recycling of sewage is one of important ways for solving the shortage of water resources and protecting the water environment.

In terms of oil fields in China, the water yield of oil fields is continuously increased along with the last stage of oil field exploitation, reaches 14 hundred million in 2016 years and is in a trend of increasing year by year, and if the water is directly discharged or cannot be discharged according to the discharge standard after treatment, underground water and soil can be polluted, even the ecological environment is damaged, and the sustainable development of economy is influenced. Therefore, the country pays more and more attention to the environmental protection and water pollution prevention and treatment work, and a new ' severest history ' environmental protection law ' is introduced in 2014. During the thirteen-five period, the general aim set by the environmental protection department is to greatly reduce the discharge of main pollutants, so the demand of sewage treatment in China from 2016 to 2021 is also increased remarkably.

Because the domestic sewage treatment technology is still in a synchronous development stage and is limited by other factors, the quality and the total amount of the oil field water treatment have a large development space, and in addition, because of the good compatibility of the produced water of the oil field, the best treatment place is to treat the reinjection stratum after reaching the standard. If the quality of the oilfield reinjection water does not meet the standard, on one hand, the oilfield reinjection water can block the stratum to increase the water injection pressure, and the problem of difficult sewage reinjection is caused. On the other hand, the quality of oil extraction is affected, so that the quality of the produced oil is poor, and certain trouble is brought to the production of oil fields. Therefore, the oil field sewage must be qualified after standard treatment and meet the requirement of oilThe reinjection can be carried out only after the reinjection index of the field reinjection water. The blocking problem and the corrosion problem are two main problems in oil field sewage reinjection, so the method is also a main control index of the oil field sewage quality, namely CO₂、O₂、H₂The corrosion of S and other gases and the corrosion caused by bacteria such as TGB, FB and SRB form the corrosion indexes of oilfield sewage reinjection, and the corrosion caused by the bacteria in the corrosion indexes has important weight. The indexes of blockage include suspended matters, particle sizes, oil content and the like, and the blockage degree is closely related to the metabolic activity of bacteria in corrosion type. Generally, the key to controlling the plugging of corrosion products is to control the corrosion-type indicator. That is, while the recycled water bacteria grow and propagate to aggravate the corrosion of pipeline equipment, the metabolites of the recycled water bacteria also increase the values of suspended solids, median particle size and the like in the blockage class. Therefore, the problem of meeting the standard of the water quality of the oilfield flooding is solved. The problems of good corrosion and blockage are mainly solved, and the problem of good bacterial corrosion is solved to the greatest extent.

In the same way, for the oil field in Xinjiang, three of the six indexes of the comprehensive standard-reaching requirement of the water injection quality are bacterial indexes, and the comprehensive standard-reaching rate of the water injection quality occupies higher weight in the investigation. Meanwhile, the water quality of the reinjection water is deteriorated due to the growth of bacteria and metabolites thereof in the process of conveying the reinjection water to a wellhead, so that the content of suspended matters is increased and the median value of the particle size is increased. In addition, the water injection quality bulletin result in 2015 of Xinjiang oil field shows that the main parameters influencing the comprehensive standard-reaching rate of the wellhead water quality are suspended matters, bacteria and median particle size, and the parameters are greatly related to the growth of the bacteria, so the bacteria control index is the most critical parameter for improving the comprehensive standard-reaching rate of the water injection quality.

China also makes a great deal of research on the corrosion problem, and the research shows that 70-80% of severe corrosion in China is caused by bacterial activity; in 1992, statistics of the oil and gas headquarters in China showed that: huge economic losses are brought to oil fields due to corrosion problems in China every year, wherein the losses caused by bacterial corrosion account for a significant proportion and are about 14 million yuan per RMB; on the fourth national corrosion meeting of 10 months as early as 2003, the Howex academicians indicate that the loss caused by corrosion in each industry of China is huge and is reduced to 5000 million yuan RMB, and the bacterial corrosion in the corrosion problems accounts for a large proportion; in 2013, the intersection of the Qingdao Donghuang drainage underground channel and the oil pipeline becomes thin and breaks due to corrosion, so that the oil pipeline leaks and explodes, and the direct economic loss caused by the corrosion reaches 7.5 hundred million RMB; in 2014, according to incomplete statistics, the corrosion loss of China is about two trillion, the corrosion loss born by all people is more than 1000 yuan, and the total corrosion value exceeds four times of natural disasters.

The risks caused by bacteria in oilfield reinjection water are mainly two aspects of damage to oil reservoirs and corrosion of pipeline equipment. TGB, SRB, FB and the like in the reinjection water can corrode metal sewage treatment equipment such as pipelines and the like through breeding metabolism on one hand. On the other hand, metabolites of microorganisms such as biological mucosa and the like can block the stratum and a water injection pipeline, so that the water injection pressure is increased, and oil layers and oil gas yield are damaged. Therefore, in order to solve the problem that the quality of the oilfield reinjection water reaches the standard, it is necessary to understand the harm of bacteria to various aspects of the oilfield injection water system in detail so as to solve the problem in a targeted manner.

The bacteria have important weight in the water quality index of oilfield reinjection water, and if a large amount of bacteria are contained in the sewage in the water injection operation, the quality problem of water injection can be influenced, so that the principle of 'injecting water well' is contradicted. On the one hand, due to the instability of the incoming liquid, the sewage can carry a large amount of nutrient substances to provide enough carbon sources for the growth of bacteria. On the other hand, the incoming liquid is continuously injected into the water injection wellhead, so that a low-temperature zone is formed around the wellhead relative to other places, and a relatively proper growth temperature is provided for the growth of bacteria, thereby being beneficial to the breeding and propagation of the bacteria. The specific analysis is as follows:

(1) bacteria produce polysaccharides through metabolism. The polysaccharide substances aggregate with each other to form biological mucosa, which can be combined with small oil drops or suspended matters in water to form bridge plugs for blocking the pore channels. On the other hand, the produced mucosal material and suspended matter are accumulated and settled into the voids in the formation to block the formation. The two functions increase the pressure of the sewage reinjection system, reduce the sewage reinjection capacity and the stratum permeability and influence the oil production yield and quality of the oil field.

(2) Aerobic bacteria can co-exist with anaerobic bacteria in an interdependent manner. For example, SRB may colonize biological mucous membranes produced by metabolism of TGB, which provide a local anaerobic niche for SRB growth that facilitates SRB breeding. The size of the bacteria is different, and the minimum size is generally larger than 0.5 μm, if the bacteria is larger than the pore size of the stratum, the stratum can be blocked, and the permeability of the stratum is reduced.

(3) The biochemical interaction between bacteria can cause changes in the properties of the crude oil. Because the smaller the molecular weight of alkane, the greater the viscosity of crude oil, bacteria can decompose large-molecular cycloparaffin and normal alkane into small-molecular hydrocarbon substances through the biochemical action, thereby increasing the viscosity of crude oil. In addition, the viscosity of the crude oil is also influenced by the content of the dissolved gas in the crude oil, the lower the content of the dissolved gas in the crude oil is, the higher the viscosity of the crude oil is, bacteria can consume the dissolved gas in water in a biochemical process, and thus the viscosity of the oil product is increased.

Therefore, effective control of the number of bacteria in the oil field is the key to reduce damage to the oil reservoir and ensure the yield and quality of oil production in the oil field.

In the 60 s of the 20 th century, the application of the bactericide in China began to start, and in the early 80 s of the 20 th century, the bactericide was widely applied. Chlorine is a bactericide widely used in the early stage of China, and has the advantages of quick bactericidal action, low price, difficult generation of drug resistance, convenient use, wide sources and the like, but has the defects of short bactericidal duration, poor stability, metal corrosion and the like, can react with organic matters in sewage to generate toxic substances such as chloroform as an intermediate product meeting chloroform, and the like, and has larger use amount under alkaline conditions, high-content organic matters and reducing substances and the like, so that the chlorine is rarely used in the oil field at present. The studies of soldiers and the like show that ClO₂The quantity of SRB, FB and TGB in the oil extraction wastewater can be well controlled, the quality of the reinjection water of the oil field is improved, and some domestic research institutions focus on developing stable chlorine dioxide generation devices. The use of the current non-oxidizing biocides occupiesThe oil field bactericide dominates the market in China, and accounts for about 72.5 percent of the oil field bactericide.

For the development of a novel bactericide, a novel quaternary phosphonium salt is developed and synthesized by Fu Jia Jun and the like, and the quaternary phosphonium salt is put into the sterilization process of oilfield reinjection water to obtain a better sterilization effect. The research of the multifunctional bactericide is slowly developed, the southern China university develops CG-A with the functions of sterilization, corrosion inhibition, flocculation and the like, and also successively develops other multifunctional bactericides, thereby opening up a new chapter for sterilization in oil field water treatment. A multifunctional medicament WX-3 with good bactericidal performance, difficult generation of drug resistance and better environmental adaptability is also developed by Jianghan oil field design institute.

The main development directions for the oxidizing bactericide in foreign countries are: high efficiency, safety, green environmental protection, and develops a plurality of bromine and chlorine dioxide bactericides. Iongport proposed that the control of microorganisms with the complex formulation was more effective than the single agent. Although foreign experts have few researches on the compounding of the bactericide, many researchers have made a lot of researches and developments on the compounding rule of the bactericide, particularly on the combination of the anionic surfactant and the cationic surfactant. According to the report of relevant data, relevant experts make researches to try to load active components of the bactericide on a high polymer material so as to improve the environmental adaptability and the bactericidal performance of the bactericide, and meanwhile, the bactericide has certain environmental protection and regeneration functions, so that the water pollution can be reduced, and the economic cost can be saved.

An authorized patent CN103478164B of China petrochemical company Limited discloses a sewage treatment agent and a preparation method thereof, belonging to the technical field of chemical agents for oil fields and preparation. The deep clean sewage treatment process is formed by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and an oxidant according to the following mass percent: 10-15% of nano titanium dioxide powder, 0.5-2% of cross-linking agent, 5-10% of surfactant, 5-10% of oxidant and the balance of water. The bactericide can be deposited on the pipe wall, a corner and the like along with liquid flow, slowly releases the main agent in a diluted manner, has lasting drug effect and no corrosion to pipelines, has the comprehensive sterilization rate of more than 90 percent to sulfate reducing bacteria, saprophytic bacteria and iron bacteria after being filled for 18 days, has the medicament filling period of 15-25 days which is 10-15 times that of common medicaments, greatly slows down the operation intensity and reduces the cost.

However, production practices show that the bactericidal rate of 90-93% after 18 days in the patent still cannot meet the requirement of the industry on lasting pesticide effect, and once the pesticide effect is invalid or the high bactericidal rate cannot be maintained for a long time, the oil field oil extraction yield and quality are directly influenced.

The reason why the sterilizing effect of the patent CN103478164B granted by the company of petrochemical industry, Inc. is hard to last is analyzed as follows: (1) with the prolonging of time, the nano titanium dioxide is easy to agglomerate due to the specific surface property, dodecyl dimethyl benzyl ammonium chloride or octadecyl dimethyl benzyl ammonium chloride serving as a surfactant in the treating agent can not provide a long-acting dispersing effect for the nano titanium dioxide, once the titanium dioxide is agglomerated, the adsorbability and the thermal stability of the titanium dioxide are greatly reduced, and the whole sterilizing effect is further influenced; (2) the bactericidal effect of sodium hypochlorite or potassium hypochlorite as a bactericide/oxidant decreases with time, and the bactericidal mechanism of sodium hypochlorite or potassium hypochlorite depends on its own oxidation property, which decreases with the change of environment and time, and finally affects the whole bactericidal effect.

Disclosure of Invention

In order to solve the problem that the sewage treatment agent in the prior art is difficult to meet the requirement of the industry on lasting drug effect, the invention provides the following technical scheme:

a process for treating deep clean sewage, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment.

The sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: the nano titanium dioxide water-based paint comprises 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant is composed of 2-amino-2-methyl-1-propanol and sodium tripolyphosphate according to the mass ratio of 1: 1.

Preferably, the bactericide consists of 2, 2-dibromo-3-nitrilopropionamide and a compound M in a mass ratio of 1:2, wherein the compound M has the following structural formula:

preferably, the particle size of the nano titanium dioxide powder is 10-50 nm.

Preferably, the crosslinking agent is epichlorohydrin.

The preparation method of the sewage treatment agent comprises the following steps:

accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.

The technical scheme of the invention has the following beneficial effects:

(1) aiming at the technical problem that the specific surface property of the nano titanium dioxide is easy to agglomerate so as to influence the overall sterilization effect in the prior art, the 2-amino-2 methyl-1-propanol and the sodium tripolyphosphate are selected as the surfactants, the 2-amino-2 methyl-1-propanol of the organic surfactant and the sodium tripolyphosphate serving as the inorganic surfactant are fully utilized to generate a synergistic dispersion promoting effect, the agglomeration effect of the nano titanium dioxide is delayed, the carrier effect and the photocatalytic effect of the nano titanium dioxide are exerted to the maximum extent, and the continuity of the high sterilization effect is realized.

(2) Aiming at the technical problem that the bactericidal effect of sodium hypochlorite or potassium hypochlorite which is taken as a bactericide/oxidant will be reduced along with the prolonging of time in the prior art so as to influence the whole bactericidal effect, the invention selects the 2, 2-dibromo-3-nitrilopropionamide and the compound M as the bactericide, because both the two bactericides have the long-acting bactericidal effect and can synergistically and complementarily promote the whole bactericidal effect by utilizing respective bactericidal mechanisms, thereby realizing the continuity of high bactericidal effect.

(3) The invention takes nano titanium dioxide micro-particles with larger specific surface, stronger adsorptivity and thermal stability as a carrier, takes a surfactant and a bactericide as main agents, the sewage treatment agent can be deposited on the pipe wall, a corner and the like along with liquid flow to slowly dilute and release the main agents, the drug effect is durable, the pipeline is not corroded, the comprehensive sterilization rate on sulfate reducing bacteria, saprophytic bacteria and iron bacteria is still more than 95 percent after the sewage treatment agent is filled for 18 days, the operation intensity is reduced, and the cost is reduced.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail with reference to the following examples and comparative examples.

Example 1

A process for treating deep clean sewage, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment.

The sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: the nano titanium dioxide water-based paint comprises 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant is composed of 2-amino-2-methyl-1-propanol and sodium tripolyphosphate according to the mass ratio of 1: 1.

The bactericide is composed of 2, 2-dibromo-3-nitrilopropionamide and a compound M according to the mass ratio of 1:2, wherein the compound M has the following structural formula:

the particle size of the nano titanium dioxide powder is 10-50 nm.

The cross-linking agent is epichlorohydrin.

The preparation method of the sewage treatment agent comprises the following steps:

accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.

Example 2

A process for treating deep clean sewage, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment.

The sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: the nano titanium dioxide water-based paint comprises 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant only comprises 2-amino-2-methyl-1-propanol and sodium tripolyphosphate according to the mass ratio of 1: 1.

The bactericide consists of 2, 2-dibromo-3-nitrilopropionamide.

The particle size of the nano titanium dioxide powder is 10-50 nm.

The cross-linking agent is epichlorohydrin.

The preparation method of the sewage treatment agent comprises the following steps:

accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.

Example 3

A process for treating deep clean sewage, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment.

The sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: the nano titanium dioxide water-based paint comprises 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant is composed of 2-amino-2-methyl-1-propanol and sodium tripolyphosphate according to the mass ratio of 1: 1.

The bactericide consists only of a compound M, and the compound M has the following structural formula:

the particle size of the nano titanium dioxide powder is 10-50 nm.

The cross-linking agent is epichlorohydrin.

The preparation method of the sewage treatment agent comprises the following steps:

accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.

Comparative example 1

A process for treating deep clean sewage, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment.

The sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant is only composed of 2-amino-2-methyl-1-propanol.

The bactericide is only composed of 2, 2-dibromo-3-nitrilopropionamide.

The particle size of the nano titanium dioxide powder is 10-50 nm.

The cross-linking agent is epichlorohydrin.

The preparation method of the sewage treatment agent comprises the following steps:

accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.

Comparative example 2

A process for treating deep clean sewage, which comprises the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment.

The sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant is only composed of sodium tripolyphosphate.

The bactericide consists only of a compound M, and the compound M has the following structural formula:

the particle size of the nano titanium dioxide powder is 10-50 nm.

The cross-linking agent is epichlorohydrin.

The preparation method of the sewage treatment agent comprises the following steps:

accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.

The following table details the types of surfactants and disinfectants used in the sewage treatment agents of examples 1 to 3 and comparative examples 1 to 2.

Numbering	Surface active agent	Bactericide
			Example 1	2-amino-2-methyl-1-propanol + sodium tripolyphosphate	2, 2-dibromo-3-nitrilopropionamide + compound M
Example 2	2-amino-2-methyl-1-propanol + sodium tripolyphosphate	2, 2-dibromo-3-nitrilopropionamide
			Example 3	2-amino-2-methyl-1-propanol + sodium tripolyphosphate	Compound M
Comparative example 1	2-amino-2-methyl-1-propanol	2, 2-dibromo-3-nitrilopropionamide
			Comparative example 2	Sodium tripolyphosphate	Compound M

The wastewater treatment agents prepared in examples 1 to 3 and comparative examples 1 to 2 were subjected to bactericidal rate evaluation (time is 18 days) with reference to SY/T5329-2012 'index and analysis method for water quality of water flooding in clastic rock oil reservoir', and the results were as follows:

numbering	Bactericide after 18 days%
		Example 1	97.0
Example 2	95.4
		Example 3	95.8
Comparative example 1	93.9
		Comparative example 2	94.3
CN103478164B	90.0～93.1

The above results show that (1) from examples 2-3 and comparative examples 1-2, when the surfactant is selected from 2-amino-2 methyl-1-propanol and sodium tripolyphosphate, the dispersibility of the nano titanium dioxide is the best, because the 2-amino-2 methyl-1-propanol as the organic surfactant and the sodium tripolyphosphate as the inorganic surfactant can generate a synergistic dispersion promoting effect, delay the agglomeration effect of the nano titanium dioxide, and maximally exert the carrier effect and the photocatalytic effect of the nano titanium dioxide. (2) From examples 1 to 3, it can be seen that, when 2, 2-dibromo-3-nitrilopropionamide and the compound M are used, the bactericidal effect of the treatment agent is superior to that of any single component (i.e., 2-dibromo-3-nitrilopropionamide or the compound M) in the same amount, because both bactericides have a long-acting bactericidal effect and can synergistically and complementarily promote the overall bactericidal effect by utilizing respective bactericidal mechanisms, so that a high-efficiency bactericidal effect can be achieved in a longer time range.

Claims (4)

1. The deep clean sewage treatment process is characterized by comprising the following steps: firstly, standing and settling the sewage, then adding a sewage treatment agent into the sewage to enable the water quality of the sewage to reach the standard, and finally carrying out filtration treatment;

the sewage treatment agent is prepared by mixing nano titanium dioxide powder, a cross-linking agent, a surfactant and a bactericide according to the following mass percent: 15% of nano titanium dioxide powder, 2% of cross-linking agent, 10% of surfactant, 10% of bactericide and the balance of water, wherein the surfactant is composed of 2-amino-2-methyl-1-propanol and sodium tripolyphosphate according to the mass ratio of 1: 1;

the bactericide is composed of 2, 2-dibromo-3-nitrilopropionamide and a compound M according to the mass ratio of 1:2, wherein the compound M has the following structural formula:

。

2. the process for treating deep clean sewage according to claim 1, wherein the particle size of the nano titanium dioxide powder is 10 to 50 nm.

3. The deep clean sewage treatment process according to claim 1, wherein the crosslinking agent is epichlorohydrin.

4. The deep cleaning wastewater treatment process according to claim 1, wherein the preparation process of the wastewater treatment agent comprises the following steps: accurately taking the components according to the mass percentage, firstly adding nano titanium dioxide powder into water, then adding a cross-linking agent, heating to 80 ℃, and then stirring for 2 hours; adding surfactant and bactericide, and stirring.