WO2021226845A1 - Chelating agent, cleaning agent, and method for preparing chelating agent - Google Patents

Abstract

The present application provides a chelating agent, a cleaning agent and a method for preparing the chelating agent. The chelating agent has a general structural formula as shown in formula (I), wherein: R₁, R₂, R₃ and R₄ are alkyl groups; M₁, M₂, M₃ and M₄ are hydrogen atoms, metal atoms, ammonium groups or organic amine groups; A is hydroxyl group or amino group. The chelating agent provided in the present application can be free of phosphorus and have strong chelating property.

Description

Chelating agent, cleaning agent and preparation method of chelating agent Technical field

This application relates to the technical field of organic chemistry synthesis, in particular to the preparation methods of chelating agents, cleaning agents and chelating agents.

Background technique

At present, common chelating agents mainly include phosphate, hydroxycarboxylic acid, aminocarboxylic acid, and carboxylic acid-containing polymers. Phosphate has a better chelating effect, but the phosphorus content causes great pollution to the environment. Sodium tripolyphosphate (STPP) is mainly used more frequently, but it has gradually faded out of the market in the global call for phosphorus restriction and prohibition. Hydroxy carboxylic acids mainly include sodium gluconate, sodium citrate, etc. Generally, the chelating performance of metal ions is poor and the cost performance is not high. Acrylic polymer is a polymer chelating agent. In addition to its chelating ability, it also has thickening and flocculation effects. Generally, it will settle in water after chelation and is also difficult to biodegrade. Aminocarboxylic acids mainly include ethylenediaminetetraacetic acid (EDTA), Hydroxyethylethylenediaminetriacetic acid (HEDTA), Diethylenetriaminepentaacetic acid (DTPA), Nitrotriacetic acid (NTA), Iminodisuccinic acid (IDS), Glutamate diacetic acid (GLDA) ), methylglycine diacetic acid (MGDA) and so on. Among them, EDTA is not easily biodegradable (OECD), NTA has potential carcinogenicity, IDS has low performance in chelating metals, GLDA and MGDA have high raw material toxicity, high equipment requirements, industrialization difficulties, high production costs, and product prices. It is expensive and often limits its widespread use in real life.

Summary of the invention

This application provides a chelating agent, a cleaning agent, and a preparation method of a chelating agent, which can provide a chelating agent with no phosphorus and strong chelating performance.

To achieve the above objective, this application provides a chelating agent, the general formula of the chelating agent is as follows:

in:

R ₁ , R ₂ , R ₃ and R ₄ are alkyl groups;

M ₁ , M ₂ , M ₃ and M ₄ are hydrogen atoms, metal atoms, ammonium groups or organic amine groups;

A is a hydroxyl group or an amino group.

Wherein, the alkyl group is -(CH ₂ ) _n -, and 0≤n≤6.

Wherein, R ₁ and R ₄ are -(CH ₂ ) ₀ -, and R ₂ and R ₃ are -CH ₂ -.

Wherein, the metal atom is Na.

In order to achieve the above objective, this application provides a method for preparing the above chelating agent, the method comprising:

Provide epoxy succinic acid (salt),

Addition reaction of epoxysuccinic acid (salt) and compound A to obtain compound B;

Substituting compound B and compound C to obtain the chelating agent;

Among them, the general structural formulas of compound A, compound B and compound C are as follows:

Compound A:

Compound B:

Compound C:

Wherein, R is R ₂ or R ₃ as defined in claim 1, M is M ₂ or M ₃ as defined in claim 1, M ₁ and M ₂ have the same meaning as in claim 1, and L is a leaving group group.

In order to achieve the above objective, this application provides another method for preparing the above chelating agent, which method includes:

Provide epoxy succinic acid (salt) and compound D;

Addition reaction of epoxysuccinic acid (salt) and compound D to obtain the chelating agent;

Among them, compound D is

R ₂ and R ₃ have the same meanings as in claim 1, and M ₅ and M ₆ are hydrogen atoms, metal atoms, ammonium groups, or organic amine groups.

Wherein, the addition reaction of epoxysuccinic acid (salt) and compound D to obtain the chelating agent includes:

Mix epoxysuccinic acid (salt) and compound D, stir for the fourth time, add _{the hydroxide containing M 7} , increase the temperature to the second temperature, and react for the fifth time to obtain the chelating agent, wherein M _{7 These are M 1} and M ₄ as defined in claim 1.

Wherein, the second temperature is 60-100°C; the fourth time is 0.5-2h; the fifth time is 2-24h.

Wherein, said providing epoxysuccinic acid (salt) includes: providing maleic acid (salt) and/or fumaric acid (salt), and cyclizing maleic acid (salt) and/or fumaric acid (salt) Oxidation reaction to obtain epoxysuccinic acid (salt).

Wherein, the epoxidation reaction of maleic acid (salt) and/or fumaric acid (salt) to obtain epoxysuccinic acid (salt) includes: making maleic acid (salt) and/or fumaric acid (salt) Acid (salt) undergoes epoxidation reaction under oxidant, catalyst and weakly alkaline or weakly acidic environment;

Wherein, the catalyst is at least one of sodium tungstate, sodium molybdate, and ammonium vanadate;

The weakly alkaline or weakly acidic environment refers to an environment with a pH of 3-8.

Wherein, the epoxidation reaction of maleic acid (salt) and/or fumaric acid (salt) in an oxidant, a catalyst and a weakly alkaline or weakly acidic environment includes:

Add the catalyst to maleic acid (salt) and/or fumaric acid (salt) and stir for the first time;

Then in the second time, the oxidant solution is added dropwise to maleic acid (salt) and/or fumaric acid (salt), while adjusting the maleic acid (salt) and/or fumaric acid (salt) by adding lye PH of the solution;

At the first temperature, react for the third time to obtain epoxysuccinic acid (salt).

Wherein, the provision of maleic acid (salt) and/or fumaric acid (salt) includes:

The maleic anhydride undergoes a hydrolysis reaction at the hydrolysis temperature to obtain maleic acid (salt) and/or fumaric acid (salt);

The provision of maleic acid (salt) and/or fumaric acid (salt), then includes:

Adjust the pH of the solution of maleic acid (salt) and/or fumaric acid (salt) to the first pH, and adjust the temperature of the solution of maleic acid (salt) and/or fumaric acid (salt) to the third temperature.

Wherein, the first time is 30-60min; the second time is 40-120min; the third time is 2-10h; the first temperature is 45-80°C; the third temperature is 40-60°C; The hydrolysis temperature is 0-75°C; the first pH is 4-8.

In order to achieve the above objective, this application provides a method for preparing the above chelating agent, the method comprising:

Provide 3-hydroxyaspartic acid and compound C;

Substituting 3-hydroxyaspartic acid and compound C to obtain the chelating agent;

Among them, compound C is

L is a leaving group, R is R ₂ or R ₃ as defined in claim 1, and M is M ₂ or M ₃ as defined in claim 1.

In order to achieve the above objective, this application provides a method for preparing the above chelating agent, the method comprising:

Provide 3-hydroxyaspartic acid and compound E;

Substituting 3-hydroxyaspartic acid and compound E to obtain compound F,

Subject compound F to a hydrolysis reaction to obtain the chelating agent;

The general structural formulas of compound E and compound F are as follows:

Compound E:

Compound F:

L is a leaving group, and R is R ₂ or R ₃ as defined in claim 1.

To achieve the above objective, the present application provides a cleaning agent, which includes the above-mentioned chelating agent.

Compared with EDTA, GLDA, MGDA, IDS, etc., the chelating agent disclosed in the present application has high chelating performance to calcium, magnesium and copper, and the chelating agent disclosed in the present application also has good chelating performance to iron ions. The chelating agent disclosed in the application shows particularly good chelating properties for calcium, magnesium, iron, copper or other metals, and has a strong chelating ability. In addition, this application is non-toxic and non-phosphorus, biodegradable, and can replace traditional chelating agents such as EDTA, DPTA, NTA, which are difficult to biodegrade or expensive. In addition, in addition to high solubility in high-concentration aqueous alkali and acid solutions, it also has excellent storage stability.

Description of the drawings

In order to more clearly describe the technical solutions in the embodiments of the present application, the following will briefly introduce the drawings that need to be used in the description of the embodiments. Obviously, the drawings in the following description are only some embodiments of the present application. For those of ordinary skill in the art, other drawings can be obtained based on these drawings without creative work.

Figure 1 is a schematic diagram of a mass spectrum of an embodiment of the chelating agent of the present application;

Fig. 2 is a schematic diagram of the hydrogen nuclear magnetic spectrum of an embodiment of the chelating agent of the present application.

Detailed ways

In order to enable those skilled in the art to better understand the technical solutions of the present application, the chelating agent provided by the present application and the preparation method thereof will be described in further detail below in conjunction with the accompanying drawings and specific embodiments.

In one aspect, this application provides an embodiment of the chelating agent of Formula I:

Among them, R ₁ , R ₂ , R ₃ and R ₄ are alkyl groups.

M ₁ , M ₂ , M ₃ and M ₄ are hydrogen atoms, metal atoms, ammonium groups or organic amine groups.

A is a hydroxyl group or an amino group.

The chelating agent provided in this application can be synthesized by any kind of raw materials and methods by those skilled in the art according to its general structural formula.

In the chelating agent of formula ₁ , R 1, R ₂ , R ₃ and R _{4 are} preferably -(CH ₂ ) _n -, 0≤n≤6, that is, n can be equal to 1, 2, 3, 4, 5 or 6. . In addition, R ₁ and R _{4 are the} same, and at least one of _{R 2} and R ₃ is different _{from R 1.} Most preferably, R ₁ and R ₄ are -(CH ₂ ) ₀ -, and R ₂ and R ₃ are -CH ₂ -.

Among them, the metal atom may be an alkali metal atom, a transition metal atom, a heavy metal atom, or a rare earth metal atom.

M ₁ , M ₂ , M ₃ and M _{4 are} preferably H and alkali metal cations. More preferably, M ₁ , M ₂ , M ₃ and M ₄ are H and Na. In addition, M ₁ , M ₂ , M ₃ and M ₄ may be different from each other. Alternatively, M ₁ , M ₂ , M ₃ and M ₄ are all the same. Alternatively, M ₁ and M _{4 are the} same, and at least one of _{M 2} and M _{3 is different from M 1} .

The chelating agent of the present application is preferably Formula Ia, Formula Ib and Formula Ic.

The chelating agent represented by formula I can form a coordination geometric structure with the metal cation.

Taking iron ions as an example, the coordination geometric structure formed by the chelating agent and iron ions is as follows:

This application takes the chelating agents represented by formulas Ia and Ib as representatives, and analyzes the chelating ability of the chelating agents disclosed in this application.

Specifically, as shown in Table 1, the chelating performance of the chelating agent disclosed in this application on calcium, magnesium, and copper has greatly exceeded that of EDTA and other similar biodegradable chelating agents, and the chelating agent disclosed in this application has a chelating effect on iron ions. The chelating performance is also very good, that is, the chelating agent disclosed in the present application shows particularly good chelating performance for calcium, magnesium, iron, copper or other metals, and has a strong chelating ability. In addition, the chelating agent disclosed in the present application has higher dispersibility, and may be more effective when used in conjunction with other chelating dispersing agents. The chelating agent disclosed in the present application can be used as a cleaning agent, and the cleaning agent may include a household detergent, an industrial cleaning agent, a water softener, and an extractant of heavy metal contaminants. The cleaning agent is widely used in printing and dyeing auxiliaries, dyeing and finishing processes, textile industry, paper industry, photosensitive materials, ceramic industry, electroplating industry and other industries. In addition, the chelating agent disclosed in the present application can also be used as a scale inhibitor and dispersant in the field of traditional industrial circulating water. In addition, the non-toxic, non-phosphorus, biodegradable, and expensive traditional chelating agents such as EDTA, DPTA, NTA, etc., disclosed in this application. In addition, the chelating agent disclosed in the present application is a colorless or light yellow transparent liquid at room temperature. It is not easy to crystallize at -25°C and below for a long time. It has high solubility in both high-concentration aqueous alkali and acid solutions. It has excellent storage stability.

In a second aspect, the present application provides a method for preparing the above-mentioned chelating agent according to the first embodiment. The method for preparing a chelating agent in this embodiment includes the following steps.

Step 11: Provide epoxysuccinic acid (salt).

Here, epoxysuccinic acid (salt) refers to epoxysuccinic acid and/or epoxysuccinate (including a form in which two carboxyl groups are a salt and a form in which only one carboxyl group is a salt).

Among them, epoxysuccinic acid (salt) can be self-made or commercially available.

In addition, epoxysuccinic acid (salt) may be cis-epoxysuccinic acid (salt) and/or trans-epoxysuccinic acid (salt).

In one implementation, cis-epoxysuccinic acid (salt) can be prepared by subjecting maleic acid (salt) to epoxidation reaction. Among them, maleic acid (salt) refers to maleic acid and/or maleic acid salt (including two carboxyl groups as a salt form and only one carboxyl group as a salt form).

Specifically, the maleic acid (salt) is subjected to the epoxidation reaction in an oxidizing agent and a catalyst, and a weakly acidic or weakly basic environment.

Among them, the oxidant may be hydrogen peroxide, but of course it is not limited to this. For example, sodium hypochlorite may also be used as the oxidant. In addition, the oxidant solution added to the maleic acid (salt) can be a hydrogen peroxide solution with a mass fraction of 25%-40%.

The catalyst may include at least one of sodium tungstate, sodium molybdate, or sodium vanadate, but of course it is not limited thereto. Optionally, the molar ratio of maleic acid (salt) to the catalyst is greater than or equal to 1:0.005. Preferably, the molar ratio of maleic acid (salt) to catalyst is 1:0.015-1:0.4.

A weakly acidic or weakly alkaline environment refers to an environment with a pH of 3-8. Preferably, the weakly acidic or weakly alkaline environment refers to an environment with a pH of 6.0-7.5. Among them, the weakly alkaline environment can be provided by LiOH, NaOH or KOH. Specifically, the weakly alkaline environment for the maleic acid (salt) reaction can be constructed by adding lye to the maleic acid (salt). The lye is a solution of LiOH, NaOH and/or KOH with a mass fraction of 25%-60%.

Further, the temperature environment for the epoxidation reaction of maleic acid (salt) may not be higher than 100°C. Preferably, the temperature environment for the epoxidation reaction of maleic acid (salt) may not be higher than 75°C. Preferably, the temperature environment for the epoxidation reaction of maleic acid (salt) may be 60-70°C.

Further, the catalyst can be added to the maleic acid (salt) first, and stirred for the first time, and then the oxidant solution is added dropwise to the maleic acid (salt) during the second time, while adjusting the maleic acid (salt) by adding lye. The pH of the acid (salt) solution. After the addition of hydrogen peroxide is completed, the temperature is raised to the first temperature, and the mixture is stirred for the third time. It can be understood that the second time is the time taken to add the oxidant solvent dropwise to the maleic acid (salt).

Optionally, the first time is 30-60 minutes. Preferably, the first time is 40-50 min. More preferably, the first time is 45 minutes.

Optionally, the second time is 40-120 min. Preferably, the second time is 60-90 min.

Optionally, the first temperature is 45-80°C. Preferably, the first temperature is 60-65°C.

Optionally, the third time is 2-10h. Preferably, the third time is 3h.

It is understandable that maleic acid (salt) can be self-made or commercially available. Exemplarily, the present application can obtain maleic acid (salt) through the hydrolysis of maleic anhydride. Preferably, the pH of the maleic anhydride solution can be adjusted to a suitable range to accelerate the hydrolysis rate of maleic anhydride. For example, the pH of the maleic anhydride solution can be adjusted by NaOH, KOH, or LiOH. And the hydrolysis rate can also be adjusted by adjusting the hydrolysis temperature of maleic anhydride. Optionally, the hydrolysis temperature of maleic anhydride is 0-75°C, such as 20°C, 25°C, or 30°C.

In addition, after the hydrolysis, the pH and temperature of the solution of the hydrolysate can also be adjusted to enable faster epoxidation. Specifically, the third temperature of the solution of the hydrolysate is adjusted to 40-60°C, and the first pH of the solution of the hydrolysate is adjusted to 4-8.

In another implementation manner, trans-epoxysuccinic acid (salt) can be prepared by subjecting fumaric acid (salt) to epoxidation reaction. Among them, maleic acid (salt) refers to maleic acid and/or maleic acid salt (including two carboxyl groups as a salt form and only one carboxyl group as a salt form). Among them, the process of preparing trans-epoxysuccinic acid (salt) with fumaric acid (salt) can refer to the process of preparing cis-epoxysuccinic acid (salt) with maleic acid (salt), which will not be repeated here.

Step 12: Addition reaction of epoxysuccinic acid (salt) and compound A to obtain compound B.

Among them, the general structural formula of compound A is

The general structural formula of compound B is

Wherein, M is M ₂ and M ₃ as defined in the first aspect, and R _{is R 2 and R 3} as defined in the first aspect. M ₁ and M _{2 are} as defined for formula I in the first aspect.

Preferably, R in compound A is -CH ₂ -, that is, compound A is aminoacetic acid.

In this way, the general structural formula of compound B prepared with aminoacetic acid and epoxysuccinic acid is

Step 13: Substituting compound B and compound C to obtain the chelating agent represented by formula (I).

Among them, the general structural formula of compound C is

Wherein, L is a leaving group. Optionally, L is Cl, I, or Br, etc., of course, it is not limited thereto.

And, M is the same as M ₂ and M ₃ defined in the first aspect. Preferably, M is Na or H.

R is as defined in the first aspect as R ₂ and R ₃ . Preferably, R is -CH ₂ -.

Preferably, compound C is chloroacetic acid. The chelate compound represented by formula Ia of the first aspect can be obtained by reacting the addition product of aminoacetic acid and epoxysuccinic acid with chloroacetic acid.

In the third aspect, this application provides a second method for preparing the above-mentioned chelating agent. The method for preparing a chelating agent in this embodiment includes the following steps.

Step 21: Provide epoxysuccinic acid (salt) and compound D.

Among them, compound D is

R ₂ and R _{3 are} as defined for formula I in the first aspect.

M ₅ and M ₆ are hydrogen atoms, metal atoms, ammonium groups, or organic amine groups.

Illustratively, M ₅ and M ₆ are hydrogen atoms, and R ₂ and R ₃ are -CH ₂ -, that is, compound D is iminodiacetic acid.

Step 22: Perform an addition reaction between epoxysuccinic acid (salt) and compound D to obtain the chelating agent.

It is understandable that the method for obtaining epoxysuccinic acid (salt) can be as described in the first embodiment of the method for preparing a chelating agent, and will not be repeated here.

Specifically, epoxysuccinic acid (salt) and compound D can be mixed first, and then stirred for the fourth time, and then _{the hydroxide containing M 7} is added, the temperature is raised to the second temperature, and the reaction is performed for the fifth time to obtain the formula I The chelating agent shown. Among them, M _{7 is the same as M 1} and M ₄ defined in the first aspect.

Optionally, the fourth time is 0.5-2h. Preferably, the fourth time is 1-1.5h.

Optionally, the second temperature is 60-100°C. Preferably, the second temperature is 80-95°C.

Optionally, the fifth time is 2-24h. Preferably, the fifth time is 3-15h.

In addition, the molar ratio of epoxysuccinic acid (salt), compound D and M ₇ atoms is about 1:1:1 to 1:5. Preferably, the molar ratio of epoxysuccinic acid (salt), compound D and M ₇ atoms is about 1:1:1.5-1:1:2.

In an application scenario, compound D is iminodiacetic acid, so that the compound represented by formula Ia of the first aspect can be obtained by reacting epoxysuccinic acid (salt) with compound D.

In the fourth aspect, the present application provides a method for preparing the above-mentioned chelating agent according to the third embodiment. The method for preparing a chelating agent in this embodiment includes the following steps.

Step 31: Provide 3-hydroxyaspartic acid and compound C.

Among them, compound C is

L is a leaving group. Optionally, L is Cl, I, or Br, etc., of course, it is not limited thereto.

M is the same as M ₂ and M ₃ defined in the first aspect. Preferably, M is Na or H.

In addition, R is the same as R ₂ and R ₃ defined in the first aspect. Preferably, R is -CH ₂ -.

Preferably, compound C is chloroacetic acid, iodoacetic acid, bromoacetic acid, or the like.

Step 32: Substituting 3-hydroxyaspartic acid and compound C to obtain the chelating agent represented by formula I.

Among them, 3-hydroxyaspartic acid and compound C can undergo a substitution reaction in an alkaline environment.

Among them, the alkaline environment can be provided by many alkaline substances. For example, the alkaline environment includes NaOH or KOH.

Taking compound C as chloroacetic acid as an example, the chelating agent represented by formula Ia can be produced by the substitution reaction of 3-hydroxyaspartic acid and compound C.

In the fifth aspect, this application provides a method for preparing the chelating agent represented by Formula I according to the fourth embodiment. The method for preparing the chelating agent represented by Formula I in this embodiment includes the following steps.

Step 41: Provide 3-hydroxyaspartic acid and compound E.

Among them, compound E:

R is as defined in the first aspect as R ₂ and R ₃ . Preferably, R is -CH ₂ -.

L is a leaving group. Optionally, L is Cl, I, or Br, etc., of course, it is not limited thereto.

Preferably, the compound E is chloroacetonitrile, iodoacetonitrile, bromoacetonitrile or the like.

Step 42: Substituting 3-hydroxyaspartic acid and compound E to obtain compound F.

Compound F:

Preferably, this application can make 3-hydroxyaspartic acid and compound E undergo a substitution reaction under the action of the second catalyst. The second catalyst is inorganic ammonium salt, organic amine or amide, etc. For example, the second catalyst is triethylamine.

For example, the general structural formula of compound F produced by 3-hydroxyaspartic acid and chloroacetonitrile under the catalysis of triethylamine is

Step 43: Make compound F undergo a hydrolysis reaction to obtain a chelating agent represented by formula I.

By hydrolyzing the cyano group of compound F to produce carboxylic acid or carboxylate, compound F is converted into a chelating agent represented by formula I.

Specifically, the compound F may undergo a hydrolysis reaction in an acidic environment or an alkaline environment. The acid-base requirement for the hydrolysis reaction of compound F can be: the pH of the reaction solution of compound F is less than or equal to 3, or greater than or equal to 10.

Various bases can provide an alkaline environment, as long as the pH of the compound F reaction solution meets the above-mentioned acid-base requirements by adding a base. For example, NaOH provides an alkaline environment.

Similarly, various acids can provide an acidic environment, as long as the pH of the compound F reaction solution meets the above-mentioned acid-base requirements by adding an acid. For example, the acidic environment is provided by hydrochloric acid.

The above method for preparing the chelating agent represented by formula I has a wide range of raw materials, low price, simple production equipment, chemical reactions in the reaction process can be synthesized in a one-pot method, high safety, no highly toxic substances involved, and product collection High rate, good performance and no negative impact on the environment. It is a green and environmentally friendly process that is easy for large-scale industrial production.

The application is specifically illustrated by the following embodiments.

Example 1:

Add 196g of maleic anhydride to a 2000mL four-necked flask, then add 200g of deionized water, and hydrolyze at 25°C for 1 hour. Then use 50% (mass fraction) of NaOH solution to adjust the pH of the reaction system to 6.0-6.5, and maintain the temperature not to exceed 45°C. After the addition, the temperature was raised to 55°C and stirred for 15 minutes. Add 14 g of sodium tungstate to the reaction system and stir for 45 minutes. In 90 minutes, the 30% hydrogen peroxide solution was added dropwise, and 50% NaOH was added to the system to adjust the pH. During the reaction, the pH=6.0-7.5, and the temperature does not exceed 75°C. After the addition of hydrogen peroxide is completed, the temperature is raised to 65°C, stirred for 3h, then 266g iminodiacetic acid is added, stirred for 1h, 160g solid sodium hydroxide is added, then the temperature is raised to 80°C, the reaction is 5h, and the temperature is lowered to obtain N,N-diethylcarboxylate The solution of acid group-3-hydroxydisuccinic acid tetrasodium salt, that is, the solution of the chelating agent represented by formula Ia, the yield: 95.33%.

Example 2:

Add 232g of maleic acid to a 2000mL four-necked flask, then add 200g of deionized water, and stir at 45°C for 1 hour. Then use 50% (mass fraction) of NaOH solution to adjust the pH of the reaction system to 5.0-6.5, and maintain the temperature not to exceed 55°C. After the addition, the temperature was raised to 55°C and stirred for 15 minutes. Add 16 g of sodium tungstate to the reaction system and stir for 45 minutes. In 90 minutes, the 30% hydrogen peroxide solution was added dropwise, and 50% NaOH was added to the system to adjust the pH. During the reaction, the pH=6.0-7.0, and the temperature does not exceed 75°C. After the addition of hydrogen peroxide is completed, the temperature is raised to 60-65°C, stirred for 3h, then 266g iminodiacetic acid is added, stirred for 1h, 160g solid sodium hydroxide is added, and then the temperature is raised to 90°C, the reaction is 8h, and the temperature is lowered to obtain N,N-di The solution of the tetrasodium salt of acetoxy-3-hydroxydisuccinic acid, that is, the solution of the chelating agent represented by formula Ia, the yield: 96.12%.

Example 3:

Add 232g of fumaric acid to a 2000mL four-necked flask, then add 200g of deionized water, and stir at 45°C for 1 hour. Then use 50% (mass fraction) of NaOH solution to adjust the pH of the reaction system to 5.0-6.5, and maintain the temperature not to exceed 55°C. After the addition, the temperature was raised to 55°C and stirred for 15 minutes. Add 20 g of sodium tungstate to the reaction system and stir for 45 minutes. In 90 minutes, the 30% hydrogen peroxide solution was added dropwise, and 50% NaOH was added to the system to adjust the pH. During the reaction, the pH=6.0-7.0, and the temperature does not exceed 75°C. After the addition of hydrogen peroxide is completed, the temperature is raised to 60-65°C, stirred for 3h, then 266g iminodiacetic acid is added, stirred for 1h, 160g solid sodium hydroxide is added, and then the temperature is raised to 90°C, the reaction is 8h, and the temperature is lowered to obtain N,N-di The solution of the tetrasodium salt of acetoxy-3-hydroxydisuccinic acid, that is, the solution of the chelating agent represented by formula Ia, the yield: 85.12%.

Example 4:

Add 196g of maleic anhydride to a 2000mL four-necked flask, then add 200g of deionized water, and hydrolyze at 25°C for 1 hour. Then use 30% (mass fraction) of KOH solution to adjust the pH of the reaction system to 6.0-6.5, and maintain the temperature not to exceed 45°C. After the addition, the temperature was raised to 55°C and stirred for 15 minutes. Add 10 g of sodium tungstate to the reaction system and stir for 45 minutes. In 90 minutes, the 30% hydrogen peroxide solution was added dropwise, and 30% KOH was added to the system to adjust the pH. During the reaction, the pH=6.0-7.5, and the temperature does not exceed 75°C. After the addition of hydrogen peroxide is completed, the temperature is raised to 60-65°C, stirred for 3h, then 266g iminodiacetic acid is added, stirred for 1h, 224g solid potassium hydroxide is added, then the temperature is raised to 95°C, the reaction is 15h, and the temperature is lowered to obtain N,N-di The solution of the tetrasodium salt of acetoxy-3-hydroxydisuccinic acid, that is, the solution of the chelating agent represented by formula Ia, the yield: 96.23%.

Example 5:

Add 232g of maleic acid to a 2000mL four-necked flask, then add 200g of deionized water, and stir at 45°C for 1 hour. Then use 30% (mass fraction) of KOH solution to adjust the pH of the reaction system to 6.0-6.5, and maintain the temperature not to exceed 45°C. After the addition is complete, the temperature is raised to 55°C and stirred for 15 minutes. Add 15 g of sodium tungstate to the reaction system and stir for 45 minutes. In 60 minutes, the 30% hydrogen peroxide solution was added dropwise, and 30% KOH was added to the system to adjust the pH. During the reaction, the pH=6.0-7.5, and the temperature does not exceed 75°C. After the addition of hydrogen peroxide is completed, the temperature is raised to 60-65°C, stirred for 3h, then 266g iminodiacetic acid is added, stirred for 1h, 224g solid potassium hydroxide is added, and then the temperature is raised to 80°C, the reaction is 15h, and the temperature is lowered to obtain N,N-di A solution of tetrasodium acetoxy-3-hydroxydisuccinic acid, that is, a solution of a chelating agent represented by formula Ia, yield: 91.23%.

Example 6:

Add 196g of maleic anhydride to a 2000mL four-necked flask, then add 150g of deionized water, 50g of methanol, and hydrolyze at 25°C for 1 hour. Then use 50% (mass fraction) of NaOH solution to adjust the pH of the reaction system to 6.0-6.5, and keep the temperature not to exceed 45°C. After the addition, the temperature was raised to 55°C and stirred for 15 minutes. Add 14 g of sodium molybdate and sodium tungstate mixed at a mass ratio of 1:1 into the reaction system, and stir for 45 minutes. In 90 minutes, the 30% hydrogen peroxide solution was added dropwise, and 50% NaOH was added to the system to adjust the pH. During the reaction, the pH=6.0-7.5, and the temperature does not exceed 65°C. After the addition of hydrogen peroxide is completed, the temperature is raised to 65°C and stirred for 2h, then 266g iminodiacetic acid is added, stirred for 1h, 160g solid sodium hydroxide is added, then the temperature is raised to 80°C, the reaction is 15h, and the temperature is lowered to obtain N,N-diethyl carboxylate A solution of tetrasodium acid 3-hydroxydisuccinic acid, that is, a solution of a chelating agent represented by formula Ia, yield: 94.23%.

In addition, by acidifying the chelating agent shown in Ia obtained in any one of Examples 1 to 6, the chelating agent shown in Formula Ib can be obtained. Wherein, the mass spectrum of the obtained product is shown in Figure 1, the measured value is 266.1, and the measured value is consistent with the theoretical value of the chelating agent shown in formula Ib, which proves that the obtained product includes the chelating agent shown in formula Ib. Combined with the hydrogen NMR spectrum of the obtained product shown in FIG. 2, it can be proved that the purity of the chelating agent represented by formula Ib in the obtained product is greater than or equal to 99%.

In addition, this application uses the following test methods to determine the chelating performance of the chelating agent to various metal ions.

(1) Determination method of magnesium ion chelation value

Weigh 1g of the sample, add 80ml of distilled water to dissolve or disperse, then add _{15ml of 10% Na 2} CO ₃ solution, and use 2mol/L NaOH standard solution to adjust the pH to 10.5. Place the prepared sample solution above in a magnetic stirring Put a stirring rod on the device, turn on the stirrer, _{and titrate with a 0.25 mol/L MgCl 2} standard solution. The end point is when the sample solution becomes slightly muddy. Record the consumption of 0.25mol/L MgCl ₂ standard solution volume as V, and do a blank control experiment at the same time, record the consumption of MgCl ₂ volume V _0.

W＝(VV ₀ )*6.0775/m

V ₀ -Blank solution consumes 0.25mol/L MgCl ₂ standard solution volume, ml;

V-consumption of 0.25mol/L MgCl ₂ standard solution volume, ml;

m-the mass of the sample, g;

6.0775-The product of Mg ²⁺ molar mass and MgCl ₂ molar concentration.

(2) Iron ion chelation value-sulfosalicylic acid color determination

Accurately weigh 1.0000g of the sample to be tested, add deionized water to dissolve it, transfer it to a 100ml volumetric flask to make the volume up to the mark, shake it well and set aside for testing. Pipette 2ml of the prepared sample solution into a 50ml Erlenmeyer flask, add 30ml of water and 5 drops of 2% sulfosalicylic acid, titrate with 0.01mol/L ferric ammonium sulfate standard solution until the solution changes from colorless to reddish end. Calculated as follows:

X=V*C*159.6*50/m

V-The volume of the sample consumed ammonium ferric sulfate solution, ml;

The concentration of C-ferric ammonium sulfate standard solution, mol/L;

M-the mass of the sample, g.

(3) Determination method of copper ion chelation value

First, accurately weigh 1g of the sample (accurate to 0.0001g) and make a 100ml solution. Then pipette 10ml sample solution into the Erlenmeyer flask, add 40ml deionized water, adjust the pH to 12 with 30% NaOH solution, and finally ^{titrate with 1g/L Cu 2+} standard solution until permanent turbidity is the end point ( Maintain the pH of the solution at 12 during the titration).

Carry out a blank test according to the above steps. The number of milligrams of complexed copper ions per gram of copolymer is the number of milligrams consumed during the titration of the standard solution.

A=(V ₁ -V ₀ )*C*10/G

V ₁ -The volume of the trivalent iron standard solution consumed by the sample solution (ml);

V ₀ -The volume of the trivalent iron standard solution consumed by the blank solution (ml);

The mass concentration of C-Cu ²⁺ standard solution (1g/L);

G-the mass of the sample (1g);

^{A-The value of Cu 2+} chelated by the sample, mg/g.

(4) Calcium ion chelation value determination method

Weigh 2g of the sample into a 250ml wide-mouth Erlenmeyer flask, add about 100ml of deionized water, then add _{10ml of 20g/L Na 2} CO ₃ solution, and add water to the mark of 150ml. Adjust the pH to 11, _{titrate with a 10mg/ml CaCl 2} standard solution under magnetic stirring conditions to produce a slightly turbid permanent precipitation, and keep the pH at about 11 during the titration. The volume V of the calcium chloride solution is consumed, and the calcium chelation value X is expressed in mg/g of calcium carbonate.

X=V*2.5*C/m

V-The volume of calcium chloride standard solution consumed by the sample, ml;

The concentration of C-calcium chloride standard solution, mg/ml;

M-the mass of the sample, g.

(5) Calcium ion dispersion performance measurement method:

Weigh 4g of the sample in a 100ml volumetric flask, dilute the sample to a constant volume of 100ml, transfer 25ml of the diluent into a 100ml wide-mouth Erlenmeyer flask, add 30ml of deionized water, add 10ml of 10% Na ₂ CO ₃ , magnetic force Titrate with 0.1mol/L calcium acetate standard solution under stirring, record the volume V of the calcium acetate standard solution consumed, and record the volume V0 of calcium acetate consumed as a blank control at the same time.

W=(VV ₀ )*C(calcium acetate)*400/m.

The above are only implementations of this application, and do not limit the scope of this application. Any equivalent structure or equivalent process transformation made using the content of the description and drawings of this application, or directly or indirectly applied to other related technical fields, The same reasoning is included in the scope of patent protection of this application.

Claims (16)

1. A chelating agent, characterized in that the general formula of the chelating agent is as follows:

   

   in:

   R ₁ , R ₂ , R ₃ and R ₄ are alkyl groups;

   M ₁ , M ₂ , M ₃ and M ₄ are hydrogen atoms, metal atoms, ammonium groups or organic amine groups;

   A is a hydroxyl group or an amino group.
2. The chelating agent according to claim 1, wherein the alkyl group is -(CH ₂ ) _n -, and 0≤n≤6.
3. The chelating agent according to claim 2, wherein R ₁ and R ₄ are -(CH ₂ ) ₀ -, and R ₂ and R ₃ are -CH ₂ -.
4. The chelating agent according to claim 1, wherein the metal atom is Na.
5. A method for preparing the chelating agent of claim 1, wherein the method comprises:

   Provide epoxy succinic acid (salt),

   Addition reaction of epoxysuccinic acid (salt) and compound A to obtain compound B;

   Substituting compound B and compound C to obtain the chelating agent;

   Among them, the general structural formulas of compound A, compound B and compound C are as follows:

   Compound A:

   

   Compound B:

   

   Compound C:

   

   Wherein, R is R ₂ or R ₃ as defined in claim 1, M is M ₂ or M ₃ as defined in claim 1, M ₁ and M ₂ have the same meaning as in claim 1, and L is a leaving group group.
6. A method for preparing the chelating agent of claim 1, wherein the method comprises:

   Provide epoxy succinic acid (salt) and compound D;

   Addition reaction of epoxysuccinic acid (salt) and compound D to obtain the chelating agent;

   Among them, compound D is

   

   R ₂ and R ₃ have the same meanings as in claim 1, and M ₅ and M ₆ are hydrogen atoms, metal atoms, ammonium groups, or organic amine groups.
7. The method for preparing a chelating agent according to claim 6, wherein the addition reaction of epoxysuccinic acid (salt) and compound D to obtain the chelating agent comprises:

   Mix epoxysuccinic acid (salt) and compound D, stir for the fourth time, add _{the hydroxide containing M 7} , increase the temperature to the second temperature, and react for the fifth time to obtain the chelating agent, wherein M _{7 These are M 1} and M ₄ as defined in claim 1.
8. The method for preparing a chelating agent according to claim 7, wherein:

   The second temperature is 60-100°C; the fourth time is 0.5-2h; the fifth time is 2-24h.
9. The method for preparing a chelating agent according to claim 5 or 6, characterized in that:

   The provision of epoxysuccinic acid (salt) includes: providing maleic acid (salt) and/or fumaric acid (salt), and epoxidizing maleic acid (salt) and/or fumaric acid (salt) Reaction to obtain epoxysuccinic acid (salt).
10. The method for preparing a chelating agent according to claim 9, wherein:

    The epoxidation reaction of maleic acid (salt) and/or fumaric acid (salt) to obtain epoxysuccinic acid (salt) includes: making maleic acid (salt) and/or fumaric acid (salt) Salt) epoxidation reaction in oxidant, catalyst and weakly alkaline or weakly acidic environment;

    Wherein, the catalyst is at least one of sodium tungstate, sodium molybdate, and ammonium vanadate;

    The weakly alkaline or weakly acidic environment refers to an environment with a pH of 3-8.
11. The method for preparing a chelating agent according to claim 10, wherein the maleic acid (salt) and/or fumaric acid (salt) is cyclized in an oxidizing agent, a catalyst, and a weakly alkaline or weakly acidic environment. Oxidation reactions include:

    Add the catalyst to maleic acid (salt) and/or fumaric acid (salt) and stir for the first time;

    Then in the second time, the oxidant solution is added dropwise to maleic acid (salt) and/or fumaric acid (salt), while adjusting the maleic acid (salt) and/or fumaric acid (salt) by adding lye PH of the solution;

    At the first temperature, react for the third time to obtain epoxysuccinic acid (salt).
12. The method for preparing a chelating agent according to claim 11, wherein said providing maleic acid (salt) and/or fumaric acid (salt) comprises:

    The maleic anhydride undergoes a hydrolysis reaction at the hydrolysis temperature to obtain maleic acid (salt) and/or fumaric acid (salt);

    The provision of maleic acid (salt) and/or fumaric acid (salt), then includes:

    Adjust the pH of the solution of maleic acid (salt) and/or fumaric acid (salt) to the first pH, and adjust the temperature of the solution of maleic acid (salt) and/or fumaric acid (salt) to the third temperature.
13. The method for preparing a chelating agent according to claim 12, wherein the first time is 30-60 min; the second time is 40-120 min; the third time is 2-10 h; and the first temperature is 45 -80°C; the third temperature is 40-60°C; the hydrolysis temperature is 0-75°C; the first pH is 4-8.
14. A method for preparing the chelating agent according to any one of claims 1 to 4, characterized in that the method comprises:

    Provide 3-hydroxyaspartic acid and compound C;

    Substituting 3-hydroxyaspartic acid and compound C to obtain the chelating agent;

    Among them, compound C is

    

    L is a leaving group, R is R ₂ or R ₃ as defined in claim 1, and M is M ₂ or M ₃ as defined in claim 1.
15. A method for preparing the chelating agent according to any one of claims 1 to 4, characterized in that the method comprises:

    Provide 3-hydroxyaspartic acid and compound E;

    Substituting 3-hydroxyaspartic acid and compound E to obtain compound F,

    Subject compound F to a hydrolysis reaction to obtain the chelating agent;

    The general structural formulas of compound E and compound F are as follows:

    Compound E:

    

    Compound F:

    

    L is a leaving group, and R is R ₂ or R ₃ as defined in claim 1.
16. A cleaning agent, characterized in that the cleaning agent comprises the chelating agent according to any one of claims 1-4.

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