阅读说明：本技术 一种组分含量稳定的含碘消毒剂的制备方法 (Preparation method of iodine-containing disinfectant with stable component content ) 是由 王振兴 黎剑坤 陈艺青 刘肖娟 符德文 谭志坚 赵一阳 于 2020-12-31 设计创作，主要内容包括：本发明公开了一种组分含量稳定的含碘消毒剂的制备方法,该方法包括将下列原料混合在一起后在50～150℃反应5～20小时,单质碘和下列七者中的任一者：(1)羧酸和醇(2)羧酸、醇和水(3)羧酸、醇、羧酸酯和水(4)醇、羧酸酯和水(5)羧酸、羧酸酯和水(6)羧酸酯和水(7)羧酸和水。本发明的含碘消毒剂中的羧酸、醇、水、酯等在碘作为催化剂的条件下通过可逆的酯化和或酯交换反应达到平衡和/或单质碘本身则在含有酸、水的条件下发生歧化反应获得稳定的单质碘、碘离子、碘酸间的平衡。该含碘消毒剂的组分稳定性,制备方便,经过长期储存(至少两年)其碘、碘化物、羧酸含量维持稳定,具有稳定的消毒杀菌效果。(The invention discloses a preparation method of an iodine-containing disinfectant with stable component content, which comprises the following steps of mixing the following raw materials together and reacting for 5-20 hours at 50-150 ℃, wherein the raw materials comprise elementary iodine and any one of the following seven materials: (1) carboxylic and alcohol (2) carboxylic acid, alcohol and water (3) carboxylic acid, alcohol, carboxylic ester and water (4) alcohol, carboxylic ester and water (5) carboxylic acid, carboxylic ester and water (6) carboxylic ester and water (7) carboxylic acid and water. The carboxylic acid, alcohol, water, ester and the like in the iodine-containing disinfectant reach balance through reversible esterification and/or ester exchange reaction under the condition that iodine is used as a catalyst, and/or elemental iodine generates disproportionation reaction under the condition of containing acid and water to obtain stable balance among the elemental iodine, iodide ions and iodic acid. The iodine-containing disinfectant has stable components, convenient preparation, stable iodine, iodide and carboxylic acid content after long-term storage (at least two years), and stable disinfection and sterilization effect.)

1. The preparation method of the iodine-containing disinfectant with stable component content is characterized by comprising the steps of mixing the following components in raw materials together, reacting for 5-20 hours at 50-150 ℃,

elemental iodine and any one of the following seven:

(1) carboxylic acids and alcohols

(2) Carboxylic acid, alcohol and water

(3) Carboxylic acid, alcohol, carboxylic ester and water

(4) Alcohol, carboxylic ester and water

(5) Carboxylic acid, carboxylic ester and water

(6) Carboxylic acid ester and water

(7) Carboxylic acid and water.

2. The preparation method according to claim 1, wherein the raw materials comprise the following components in parts by weight:

0.5-10% of elemental iodine, 5-30% of carboxylic acid and 65-90% of alcohol, or

0.5-10% of elemental iodine, 5-25% of water, 5-30% of carboxylic acid and 38-80% of alcohol, or

0.5-10% of elemental iodine, 5-30% of water, 5-25% of carboxylic acid, 32-72% of alcohol, 5-25% of carboxylic ester, or

0.5-10% of elemental iodine, 10-30% of water, 25-65% of alcohol, 15-45% of carboxylic ester, or

0.5-10% of elemental iodine, 5-30% of water, 5-35% of carboxylic acid, 30-75% of carboxylic ester, or

0.5-10% of elemental iodine, 5-40% of water and 55-90% of carboxylic ester, or

0.5-10% of elemental iodine, 50-90% of water and 6-45% of carboxylic acid.

3. The method according to claim 1 or 2, wherein the carboxylic acid is selected from the group consisting of citric acid, salicylic acid, benzoic acid, phthalic acid, terephthalic acid, trimellitic acid, trimesic acid, pyromellitic acid, 1,3, 5-pentaric acid, 1,3, 5-cyclohexanetricarboxylic acid, oxalic acid, malonic acid, succinic acid, glutaric acid, adipic acid, formic acid, acetic acid, propionic acid, butyric acid, lactic acid, and gallic acid.

4. The production method according to claim 1 or 2, characterized in that the alcohol is an alcohol having less than 10 carbons in a molecule.

5. The method according to claim 4, wherein the alcohol is selected from the group consisting of ethanol, n-propanol, isopropanol, n-butanol, isobutanol, sec-butanol, tert-butanol, ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, glycerol, and pentaerythritol.

6. The production method according to claim 1 or 2, wherein the carboxylic acid ester is an ester of the carboxylic acid with the alcohol.

7. The method according to claim 6, wherein the carboxylic acid ester is selected from the group consisting of citric acid, salicylic acid, benzoic acid, phthalic acid, terephthalic acid, trimellitic acid, trimesic acid, pyromellitic acid, 1,3, 5-pentaric acid, 1,3, 5-cyclohexanetricarboxylic acid, oxalic acid, malonic acid, succinic acid, glutaric acid, adipic acid, formic acid, acetic acid, propionic acid, butyric acid, lactic acid, and gallic acid, and a mixture of one or more carboxylic acid esters of ethanol, n-propanol, isopropanol, n-butanol, isobutanol, sec-butanol, t-butanol, ethylene glycol, diethylene glycol, triethylene glycol, glycerol, and pentaerythritol.

8. The method according to claim 1 or 2, wherein the reaction temperature is 70 to 90 ℃ and the reaction time is 8 to 16 hours.

9. The production method according to claim 2, comprising mixing the following components together in the starting materials and reacting at 85 ℃ for 10 hours,

the raw materials comprise the following components:

15% of citric acid, 5% of elementary iodine, 60% of glycerol and 20% of water.

10. The iodine-containing disinfectant prepared by the preparation method as set forth in any one of claims 1 to 9, wherein the content of each component changes by less than 5% after the disinfectant is stored for 2 years under normal conditions.

Technical Field

The invention belongs to the field of disinfectants, and particularly relates to an iodine-containing disinfectant with stable component content.

Background

Iodine disinfectants are widely used in various aspects of industrial production and daily life, but the stability of iodine-containing disinfectants is always a very challenging subject. The main reason for the instability of iodine-containing disinfectants is the reactive nature of the iodine species. In order to stabilize elemental iodine, an iodide such as potassium iodide, sodium iodide, or the like is generally added; or adding acid, such as citric acid, salicylic acid, sulfuric acid, phosphoric acid, etc.; or iodate is added into the system, such as iodide and iodate are added into the system of complex iodine, which can play a role in stabilizing the iodine disinfectant to a certain extent, but the content of the iodine disinfectant still changes obviously after the iodine disinfectant is placed for a long time. For example, in the "influence and effect improvement of the PVP-K30 complexing agent on the sterilization effect of povidone iodine" (talking wisdom, Sun Wei, Tangchen, Gejiaming, Lishi, Tianye, Wanxi; influence and effect improvement of the PVP-K30 complexing agent on the sterilization effect of povidone iodine [ J ]. Jiangsu preventive medicine, 2019,30(1):10-12), it is mentioned that the addition of a certain amount of potassium iodate in a system of an iodophor disinfectant can increase the stability of the system by reducing the amount of potassium iodide, and the literature results show that: after the iodophor A, B, C is stored for 14 days at the temperature of (54 +/-1), the effective iodine reduction rates are respectively 12.10%, 21.43% and 7.86%; after being stored for 90 days at the temperature of (37 +/-1) DEG C, the reduction rates of the effective iodine are respectively 10.54 percent, 17.79 percent and 5.29 percent. (in the above results, A, B is obtained by complexing povidone with iodine at different places and then compounding with potassium iodide, etc., and C is a system of preparing povidone-iodine and adding potassium iodate, which is better than the povidone used in A, B). From the results, it can be seen that the addition of potassium iodate or the like is advantageous in stability, but the stability is yet to be further improved. The instability of the iodine disinfectant in the system influences the disinfection performance and shelf life of products, so that the products cannot have the defect of long-term stability, the pressure during production, stock, storage and transportation is increased, and the stability of the disinfection effect which influences the actual disinfection effect is also influenced.

When the existing iodine-containing disinfectant is prepared, particularly when iodide (such as potassium iodide) and/or iodate (such as potassium iodate) are used as the stabilizing agent, different feeding sequences lead to different iodine simple substance contents in the newly prepared iodine-containing disinfectant, so that the difference among different batches is caused, and the influence is caused on industrial production.

Therefore, the preparation method of the iodine-containing disinfectant with stable components, particularly more stable iodine content and consistent iodine-containing disinfectant content among batches has very important significance.

Disclosure of Invention

Aiming at the problem of unstable component content of the iodine-containing disinfectant in the prior art, the invention aims to provide the iodine-containing disinfectant with stable component content, which has stable contents of iodine, iodide and carboxylic acid after long-term storage (at least two years) and stable disinfection and sterilization effects.

The invention adopts the following technical scheme to realize the purpose:

a preparation method of iodine-containing disinfectant with stable component content comprises the following steps of mixing the following components in raw materials together, reacting for 5-20 hours at 50-150 ℃,

elemental iodine and any one of the following seven:

(1) carboxylic acids and alcohols

(2) Carboxylic acid, alcohol and water

(3) Carboxylic acid, alcohol, carboxylic ester and water

(4) Alcohol, carboxylic ester and water

(5) Carboxylic acid, carboxylic ester and water

(6) Carboxylic acid ester and water

(7) Carboxylic acid and water.

Preferably, the raw materials comprise the following components in percentage by weight:

0.5-10% of elemental iodine, 5-30% of carboxylic acid and 65-90% of alcohol, or

0.5-10% of elemental iodine, 5-25% of water, 5-30% of carboxylic acid and 38-80% of alcohol, or

0.5-10% of elemental iodine, 5-30% of water, 5-25% of carboxylic acid, 32-72% of alcohol, 5-25% of carboxylic ester, or

0.5-10% of elemental iodine, 10-30% of water, 25-65% of alcohol, 15-45% of carboxylic ester, or

0.5-10% of elemental iodine, 5-30% of water, 5-35% of carboxylic acid, 30-75% of carboxylic ester, or

0.5-10% of elemental iodine, 5-40% of water and 55-90% of carboxylic ester, or

0.5-10% of elemental iodine, 50-90% of water and 6-45% of carboxylic acid.

Preferably, the carboxylic acid is selected from one or more of citric acid, salicylic acid, benzoic acid, phthalic acid, terephthalic acid, trimellitic acid, trimesic acid, pyromellitic acid, 1,3, 5-pentanedioic acid, 1,3, 5-cyclohexanetricarboxylic acid, oxalic acid, malonic acid, succinic acid, glutaric acid, adipic acid, formic acid, acetic acid, propionic acid, butyric acid, lactic acid, and gallic acid.

Preferably, the alcohol is an alcohol having less than 10 carbons in the molecule.

Preferably, the alcohol is selected from one or more of ethanol, n-propanol, isopropanol, n-butanol, isobutanol, sec-butanol, tert-butanol, ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, glycerol and pentaerythritol.

Preferably, the carboxylic acid ester is formed by the carboxylic acid and the alcohol.

Preferably, the carboxylic ester is selected from one or more of citric acid, salicylic acid, benzoic acid, phthalic acid, terephthalic acid, trimellitic acid, trimesic acid, pyromellitic acid, 1,3, 5-pentanetricacid, 1,3, 5-cyclohexanetricarboxylic acid, oxalic acid, malonic acid, succinic acid, glutaric acid, adipic acid, formic acid, acetic acid, propionic acid, butyric acid, lactic acid or gallic acid, and one or more of carboxylic esters of ethanol, n-propanol, isopropanol, n-butanol, isobutanol, sec-butanol, tert-butanol, ethylene glycol, diethylene glycol, triethylene glycol, glycerol or pentaerythritol.

More preferably, the carboxylic acid ester is selected from the group consisting of acetic acid, citric acid, 1,3, 5-pentanedioic acid, 1,3, 5-cyclohexanetricarboxylic acid, and one or more mixtures of carboxylic acid esters of ethanol, n-propanol, diethylene glycol, triethylene glycol, glycerol, pentaerythritol.

Preferably, in the preparation method, the reaction temperature is 70-90 ℃ and the reaction time is 8-16 hours.

Preferably, the preparation method comprises the following steps of mixing the following raw materials together and reacting at 78 ℃ for 15 hours, wherein the raw materials comprise the following components: 2% of elementary iodine, 10% of anhydrous citric acid, 68% of ethanol and 20% of water.

Preferably, the above preparation method comprises mixing the following components in raw materials together and reacting at 85 ℃ for 10 hours, wherein the raw materials comprise the following components: 15% of citric acid, 5% of elementary iodine, 60% of glycerol and 20% of water.

After the disinfectant prepared by the method is stored for 2 years under conventional conditions, the content of each component changes by less than 5%.

The iodine-containing disinfectant prepared by the method can be directly used for disinfection, and can also be used after being diluted by water. When the disinfectant is diluted by water for use, the disinfectant can be directly added into water to be diluted for dilution, preferably 50-1000 times, and can be disinfected by soaking, spraying and the like.

The preparation method of the iodine-containing disinfectant comprises the step of heating the raw materials at 50-150 ℃ to prepare the iodine-containing disinfectant. The iodine disinfectant has stable components, the contents of elemental iodine and carboxylic acid are kept stable after long-term storage (at least two years), the iodine disinfectant has stable disinfection and sterilization effects, expensive iodides and/or iodic acid compounds (iodic acid compounds refer to iodic acid or iodate) are not needed to be used as stabilizers, the cost is low, the preparation process is simple, complex and accurately set feeding sequence and process are not needed, the contents of the components of disinfectant products in different batches are consistent, and the iodine disinfectant is suitable for industrial mass production.

Detailed Description

Elemental iodine undergoes disproportionation under alkaline conditions, and the ionic reaction formula can be generally expressed by the following equation: 3I₂+6OH^-＝5I^-+IO₃ ^-+3H₂And O. It is believed that the reaction is irreversible and eventually ends up with the complete reaction of elemental iodine with hydroxide ions to form iodide and iodate ions, and we can see from the equation that the hydroxide ions are consumed to form water throughout the process, and therefore the pH of the system should be raised after the reaction has taken place. In the course of research on iodine-containing disinfectants, the inventors found that under acidic conditions, the reaction is converted from irreversible reaction to reversible equilibrium reaction, and the ionic reaction formula can be expressed as:(or)。HIO₃May be partially ionized in this system. When the balance is finally achieved, the elementary iodine (possibly the elementary iodine and the iodide ion form combined combination), the iodide ion, the iodic acid and/or iodate ion, water and hydrogen ion (acid) in the system reach a certain balance, so that the whole system can be stable.

For elemental iodine, elemental iodine and iodine anion (I)^-) May generate I in between₃ ^-、I₅ ^-、I₅ ^-… …, etc., making the overall system very complex.

The prior iodine-containing disinfectants, iodides (such as potassium iodide) and iodate (potassium iodate) are commonly used as stabilizers of the iodine-containing disinfectants, which are related to the disproportionation reaction of the iodine and the promotion of the dissolution of the elementary iodine by the iodides. In addition, the prior art also mentions that potassium iodate and other substances are added into a system containing iodine simple substances and iodide to improve the stability of the iodine content of the iodine-containing disinfectant, which can really achieve certain effects (such as talking about wisdom, Sun Wei, Tang Chen, Ge Jian Ming, Li Xi, Tian, Wang xi, PVP-K30 complexing agent has influence on the sterilization effect of povidone iodine and effect improvement [ J ] Jiangsu preventive medicine, 2019,30(1):10-12), and also should be related to the disproportionation reaction of the iodine simple substances, and many prior arts also mention iodine-containing disinfectants containing iodide (such as potassium iodide, sodium iodide and the like) and/or iodate (potassium iodate), but the inventor also notes that according to the content recorded in the above documents, although the stability of the iodine-containing disinfectant component containing iodate is obviously improved when the iodate is added into the iodine-containing disinfectant, however, after storage, the iodine content of the disinfectant containing iodine still decreases to about half, namely, the iodine content still decreases more obviously (more than 5 percent) (particularly, see the results disclosed in the above documents). Therefore, it is still insufficient to stabilize the iodine content of iodine-containing disinfectants by directly adding iodate, and the like.

The inventor finds that the reason why the iodine content can be partially stabilized by adding iodide and/or iodate and the like, but the reduction of the iodine content cannot be completely inhibited is actually related to the complex reaction of the iodine-containing disinfectant through experimental research:

reactions that may occur in disinfectants containing elemental iodine include:

(complete dissociation of iodic acid),(partial dissociation of iodic acid should occur mainly in systems with high acid content),Various reaction chambersMutual inhibition and mutual influence make the quantitative calculation of each component difficult; on the other hand, the order and amount of addition will also have a great influence on the system, for example, a solution system in which potassium iodide and potassium iodate are dissolved and mixed first and then added to a solution containing iodine simple substance, potassium iodide and acid, or a solution system in which potassium iodide and potassium iodate are dissolved and mixed and then added to iodine simple substance and potassium iodide after being mixed with acid will have a very obvious influence on the composition of the system. If the mixed solution of partial potassium iodide and potassium iodate is directly added into a system containing iodine, potassium iodide and acid, the iodine in the system can inhibit the reverse reaction of the disproportionation reaction of the iodine, so that the change of the iodine content in the system is not too obvious; however, if part of the potassium iodide and the potassium iodate is mixed with the acid and then mixed with the mixed solution of the iodine elementary substance and the potassium iodide, the iodine elementary substance is rapidly generated (and the iodine elementary substance may be separated out) under the condition that the acid exists in the potassium iodide and the potassium iodate, and then the potassium iodide and the potassium iodate are added into the mixed solution of the iodine elementary substance and the potassium iodide, so that the content of the iodine elementary substance is higher, and the phenomenon of larger content of iodine in the later period is caused; and the feed rate and the like at the time of formulation may also make the stability between batches poor. This largely causes instability in batch production, which makes production difficult. And the difference of the content and the stability of each batch not only causes great trouble to production, but also causes great inconvenience to use, and reduces the confidence of users in the use of products and the doubtful worry about the actual killing effect.

From the above, it can be seen that the various reactions of iodine are complicated, the process of the feeding sequence of the various components is strictly controlled, and the feeding amount of each raw material is also strictly controlled, otherwise significant fluctuations in the product content and stability are caused, which are caused by the complexity of the reaction of iodine and the instability of iodine. The inventor finds that the preparation method which uses simple substance iodine as raw material and utilizes the reversible reaction among the components in various raw materials of the iodine-containing disinfectant to balance the components of the iodine-containing disinfectant can save the complex steps of adding iodide and iodic acid compounds and the defect of strictly and accurately controlling the process steps, and can well control the content and the stability of the components.

And the inventor's stability study on the formulation containing carboxylic acid, alcohol, iodine, iodide and water finds that the carboxylic acid content is reduced even in the case of being left at room temperature, and detects that the esterification product of carboxylic acid and alcohol is generated, for example, after the iodine-containing disinfectant containing citric acid and ethanol is left for a long time, more components of monoethyl citrate and diethylene citrate are detected, and a small amount of tri-citrate is detected; esterified products of citric acid and glycerol were detected in iodine-containing disinfectants containing citric acid and glycerol; while the ethyl acetate component was detected in the system containing acetic acid and ethanol; moreover, the formation of esterification products increases with increasing temperature and is a significant cause of destabilization of disinfectant compositions containing carboxylic acid and alcohol components. That is, when carboxylic acid and alcohol exist in the iodine-containing disinfectant, ester is generated by the carboxylic acid and the alcohol under the catalysis of elementary iodine at normal temperature, and the reaction is as follows:

this reaction results in a decrease in the acid content of the system, resulting in a pH (H) in the system⁺) And the change of water amount, and the hydrogen ions and the water are associated with the disproportionation reaction of the iodine, so that the reaction balance of the iodine and the water in the system is influenced, and the content of the iodine is changed.

The present invention has been accomplished on the basis of the above-mentioned research by utilizing the above-mentioned complex reactions of different components in an iodine-containing disinfectant using only elemental iodine as an iodine source raw material to obtain a stable iodine-containing disinfectant.

In the description of the present invention, "plural" means two or more.

The stable iodine-containing disinfectant is prepared by reacting raw materials for 5-20 hours at 50-150 ℃, wherein the raw materials comprise the following components:

elemental iodine and any one of the following seven:

(1) carboxylic and alcohol (2) carboxylic acid, alcohol and water (3) carboxylic acid, alcohol, carboxylic ester and water (4) alcohol, carboxylic ester and water (5) carboxylic acid, carboxylic ester and water (6) carboxylic ester and water (7) carboxylic acid and water. The components in the final iodine-containing disinfectant are obtained after the components in the raw materials reach balance through reversible reaction, and the iodine-containing disinfectant has the characteristic of long-term stable content.

The simple substance iodine in the raw material is the main disinfecting and sterilizing component in the iodine-containing disinfectant. The mass percentage of the elementary iodine is 0.3-8%, more preferably 0.5-4%, and still more preferably 1-3%.

For iodine, only elementary iodine is selected as the only source of iodine in the disinfectant, the balance of various iodine-containing substances, such as hydrogen iodide, iodic acid, etc., is obtained through the disproportionation reaction of iodine, and the amount of each substance is limited by the reaction balance.

In the method for preparing the iodine-containing disinfectant of the present invention, stable iodine-containing disinfectant can be obtained by selecting inorganic acid such as sulfuric acid, phosphoric acid and the like as a raw material as well according to the reaction described above, but in consideration of biocompatibility, safety in use and the like, organic acid is selected, and further carboxylic acid is selected; compared with inorganic acid, the carboxylic acid has milder property and better biocompatibility, and iodine can exert more excellent disinfection and sterilization effects in an acidic medium environment. Thus carboxylic acid is one of the essential starting materials for the present invention.

In the present description, the carboxylic acid is preferably water-soluble and/or alcohol-and/or ester-soluble, and more preferably a carboxylic acid that can undergo esterification reaction under catalysis of elemental iodine. Such carboxylic acids include, but are not limited to, citric acid (citric acid), salicylic acid, benzoic acid, phthalic acid, terephthalic acid, trimellitic acid, trimesic acid, pyromellitic acid, 1,3, 5-pentanedioic acid, 1,3, 5-cyclohexanetricarboxylic acid, oxalic acid, malonic acid, succinic acid, glutaric acid, adipic acid, formic acid, acetic acid, propionic acid, n-butyric acid, lactic acid, and gallic acid. From the viewpoint of water solubility, alcohol solubility, and acidity and its own sterilizing effect, acetic acid, citric acid, salicylic acid, 1,3, 5-pentanedioic acid, 1,3, 5-cyclohexanetrioic acid, oxalic acid, malonic acid are preferable.

In the preparation method of the iodine-containing disinfectant, the raw material alcohol can be used as a solvent for dissolving acid and ester, iodine and iodide, and the preparation method is carried outIn the formula research, more alcohol is found to have the obvious function of stabilizing the elemental iodine and preventing the content reduction in the iodine-containing disinfectant formula. In the formulation of alcohol-free iodine-containing disinfectants, the content of elemental iodine is reduced and the iodine negative ions (I)^-) The increase of the content occurs simultaneously, which seriously affects the stability of the disinfectant product and the subsequent disinfection and sterilization effect. The reason for this should be the absence of the iodate compound in the disproportionation reaction of iodine as described above. A larger amount of alcohol means less water, so that the driving force for the disproportionation reaction of iodine is reduced, reducing the variation in iodine content. The interaction with other components of the system, such as acids, esters, etc., in the presence of alcohol may also be responsible for stabilizing the disinfectant.

In the description of the present invention, alcohols having greater water solubility and better solubility for acids and esters are generally selected, preferably alcohols having less than 10 carbon atoms in the molecule. Alcohols having less than 10 carbon atoms in the molecule include, but are not limited to, ethanol, n-propanol, isopropanol, n-butanol, isobutanol, sec-butanol, tert-butanol, ethylene glycol, diethylene glycol, triethylene glycol, tetraethylene glycol, glycerol, pentaerythritol and benzyl alcohol. Ethanol, n-propanol, ethylene glycol, diethylene glycol, triethylene glycol, glycerol, pentaerythritol or mixtures thereof are preferred. Although methanol also has good material solubility and can obtain iodine-containing disinfection solution with long-term stability, methanol is not selected as the composition of the formula in the application in consideration of the toxicity of methanol.

The raw material carboxylic ester used in the preparation method of the iodine-containing disinfectant has very important effect on the stability of the content of the components in the formula of the iodine-containing disinfectant. The absence of esters is also one of the important reasons for the instability of the existing iodine disinfectant formulas containing acid and alcohol. In the preparation process, the ester can be used as a raw material to directly inhibit the reaction of acid alcohol, or the stability of the obtained system can be improved through reaction generation.

Elemental iodine has been reported as a catalyst for the reaction of carboxylic acids and alcohols to esters. Elemental iodine has been reported as a mild Lewis acid to catalyze the esterification and transesterification of carboxylic acids with alcohols as well as the esterification reaction as well as the transesterification reaction, as described in K.Ramalinga, P.Vijayalakshmi, T.N.B.Kaimal.A. mil and effective method for esterification and transesterification of by iodine [ J ] Tetrahedron Letters,2002,43: 879-. On the other hand, it is also a common practice to remove the water produced by the reaction using a water-carrying agent so that the esterification reaction proceeds as completely as possible, and in a system where the amount of water is small, the influence of disproportionation of iodine on the esterification reaction is certainly small.

Unlike the above-mentioned documents for the purpose of obtaining an esterified product, the inventors have unexpectedly found, based on the characteristics of iodine-containing disinfectants, that the equilibrium of acid, alcohol, ester, and water is achieved by using the composition of the disinfectant raw material having elemental iodine as the only iodine source for the esterification reaction and/or the transesterification reaction under high temperature conditions (if the reaction can occur, for example, if the system does not contain alcohol and ester but contains acid, water, and elemental iodine, the esterification reaction does not occur); meanwhile, iodine, iodide, iodic acid compounds, water and acid (hydrogen ions) are balanced under the condition that a certain amount of water exists; finally, the composition containing elementary iodine, iodide, carboxylic acid, alcohol, ester, water and other substances (if existing) in an equilibrium state is obtained. In the process, the iodine-containing disinfectant with stable composition can be obtained by heating reaction only by controlling the initial proportion of the raw materials; further, only the amount of elemental iodine may be controlled for iodine-containing compounds, and the amount and ratio of iodide, iodic acid compounds need not be controlled.

The iodine-containing disinfectant obtained through the balancing process can control the balance moving range within a very small range by the balance relation of each component in the composition even if the temperature of the system changes again, and the range requirement of the composition stability is met. And when the temperature is restored to the normal storage temperature, the components return to the standard equilibrium state, so that the components are restored to the equilibrium components, and the iodine-containing disinfectant with stable component content is obtained.

Different from the esterification reaction reported in the above literature, the preparation method of the disinfectant disclosed by the invention does not aim to obtain an esterification product, but focuses more on the stability and change rule of iodine, and does not add a water-carrying agent to reduce the water content in order to improve the esterification yield; instead, the system is controlled to contain a certain amount of water content in order to control the amount of the esterification product.

The disinfectant prepared by the method of the present invention is different from the disinfectant to which iodide (hydrogen iodide or hydroiodide) and/or iodate are added as described above. The method only uses the elemental iodine as the only iodine source of the disinfectant, and utilizes the reversible reaction of the elemental iodine and water to generate iodide ions and iodate ions, which is similar to the esterification reaction which uses the elemental iodine as the catalyst; the process of the present invention differs from the esterification reactions reported in the above-mentioned documents in that the present invention also concerns the change or law of change of the iodine content. In the preparation method of the invention, water is always contained in the raw material formula or the product composition, and acid always exists in the system, under the composition, the iodine element can certainly react with the water to generate a reaction of iodine ions (hydroiodic acid) and iodate ions (or iodic acid), which can cause the content of the iodine element to change. The preparation method of the invention is just to use the point to obtain the balance of iodine simple substance, iodine ions, iodate ions (or iodic acid) and the like in the disinfectant formula. Since the reaction can be self-balanced, the preparation method of the present invention does not specifically require that the amount of water be limited to a specific range which is relatively low. The amount of water, the pH value and the amount of carboxylic acid in a natural system influence the proportion of various iodides when the system is stable, but the method can always achieve self balance, which is the characteristic of the method.

On the other hand, the amount of water also affects the equilibrium esterification reaction, and the amount of water is relatively large, so that the ester content in the final equilibrium system is relatively small, and the ester content is relatively large when the amount of water is small.

The iodine-containing disinfectant prepared by the preparation method of the invention through the reaction of the raw materials under the heating condition to obtain the equilibrium product can basically meet the requirement of keeping the stability of the iodine content after being placed at room temperature for two years.

In order to obtain the iodine-containing disinfectant with stable content of the components, the preparation method of the invention mixes the elementary iodine and 2 to 4 of carboxylic acid, alcohol, water and carboxylic ester, and then the system reaches an equilibrium state mainly through the reaction of the iodine and the water and the esterification reaction and/or the hydrolysis reaction of the carboxylic ester and/or the alcohol exchange reaction of the carboxylic ester and/or the acid exchange reaction of the carboxylic ester under the catalysis of the iodine. Specifically, the raw materials for preparing the iodine-containing disinfectants of the present invention include any one of the following seven in addition to elemental iodine: (1) carboxylic and alcohol (2) carboxylic acid, alcohol and water (3) carboxylic acid, alcohol, carboxylic ester and water (4) alcohol, carboxylic ester and water (5) carboxylic acid, carboxylic ester and water (6) carboxylic ester and water (7) carboxylic acid and water.

The invention will be further illustrated with reference to the following specific examples. The specific embodiment is implemented on the premise of the technical scheme of the invention, and a detailed implementation mode and an operation process are given. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. The experimental methods in the following examples, which are not specified under specific conditions, are generally carried out under conventional conditions. Unless otherwise indicated, ratios and percentages are by weight.

The detection method of elemental iodine and acid in the following examples is as follows:

elemental iodine: the product is precisely measured and weighed with 10ml, and is placed in an iodine bottle and titrated by sodium thiosulfate titration solution (0.1mol/L) until the solution is colorless. The elemental iodine content was calculated as follows: na (Na)₂S₂O₃+I₂＝Na₂S₄O₆+₂NaI. If the acid is poorly soluble in water, a suitable amount of ethanol may be added prior to titration.

Carboxylic acid: the acid amount (in carboxylic acid) of the system is determined by acid-base titration, and specifically comprises the following steps: and (3) adding phenolphthalein indicator solution into the solution with the iodine content measured, titrating with sodium hydroxide titration solution (1mol/L) until the color of the system turns pink, and calculating the content of carboxylic acid.

And (3) stability testing:

the stability tests in the following examples were carried out by means of accelerated tests. The method specifically comprises the following steps: and (3) sealing the disinfectant in a hydrothermal reaction kettle, placing the hydrothermal reaction kettle in a constant-temperature drying box, starting timing, heating to 80 ℃ within 2 hours, starting timing when the temperature is raised to 80 ℃, preserving heat for 8 hours, stopping heating, naturally cooling to room temperature along with a furnace, taking a period of 24 hours from the start of timing, and then continuously repeating the process for 10 cycles. The contents of elemental iodine and carboxylic acid were measured by sampling before accelerated test (referred to as 0 day) and after 10 days of circulation (referred to as 10 days) after preparation of the disinfectant. It has been shown from earlier experimental results that one cycle (1 day) for the iodine-containing disinfectants of the present invention corresponds to approximately 2.5 months of storage at room temperature and 10 cycles corresponds to approximately 2 years.

Example 1:

1.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

2% of elementary iodine, 10% of anhydrous citric acid and 88% of anhydrous ethanol.

1.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

adding 20g of elemental iodine into about 300g of absolute ethyl alcohol, and stirring and dissolving to obtain an A1 solution; dissolving 100g of citric acid in 400g of absolute ethyl alcohol to obtain a B1 solution; adding the B1 solution into the A1 solution under stirring, fully stirring, adding the balance of about 180g of absolute ethyl alcohol into the mixed solution under stirring to obtain a uniform solution, namely disinfectant raw material solution; and (3) reacting the raw material solution for 12h at the temperature of 70 ℃ in a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

1.3 the composition of the iodine disinfectant and carboxylic acid is determined (according to the detection method of the iodine and the carboxylic acid): 1.41 percent of elementary iodine and 1.20 percent of carboxylic acid (calculated by citric acid). (since the system may generate mono-and diethyl-citrates containing carboxyl groups, both normalized to citric acid when titrated with sodium hydroxide; and possibly small amounts of hydriodic acid, iodic acid, etc. normalized to carboxylic acid.)

1.4, performing accelerated test on the disinfectant prepared in the step 1.2 at 80 ℃ for 10 cycles, wherein the iodine simple substance and carboxylic acid contents of the disinfectant after the accelerated stability test are respectively as follows: 1.39% and 1.18%, and the change rates are respectively as follows: 1.42 percent and 1.67 percent, which are both less than 5 percent, meet the standard of product stability.

Example 2:

2.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

2% of elementary iodine, 10% of anhydrous citric acid, 68% of ethanol and 20% of water.

2.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

adding 20g of elemental iodine into about 300g of absolute ethyl alcohol, and stirring and dissolving to obtain an A2 solution; dissolving 100g of citric acid in 380g of absolute ethyl alcohol to obtain a B2 solution; adding the B2 solution into the A2 solution under stirring, fully stirring, and adding 200g of water into the mixed solution under stirring to obtain a uniform solution, namely disinfectant raw material solution; and (3) reacting the raw material liquid for 15h at 78 ℃ in a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

2.3 the composition of the iodine disinfectant (according to the detection method of the iodine and the carboxylic acid) is determined as follows: 1.30 percent of elementary iodine and 3.35 percent of carboxylic acid (calculated by citric acid).

2.4, performing accelerated test on the disinfectant prepared in the step 2.2 at 80 ℃ for 10 cycles, wherein the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 1.29% and 3.31%, and the change rates are respectively as follows: 0.77 percent and 1.19 percent, which are both less than 5 percent, meet the standard of product stability.

Example 3:

3.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

10% of acetic acid, 5% of elemental iodine, 15% of ethyl acetate, 50% of ethanol and 20% of water.

3.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

adding 50g of elemental iodine into 300g of absolute ethyl alcohol, and stirring and dissolving to obtain an A3 solution; mixing 100g of acetic acid, 200g of ethanol and 150g of ethyl acetate to obtain a B3 solution; adding the B3 solution into the A3 solution under stirring, fully stirring, and adding 200g of water into the mixed solution under stirring to obtain a uniform solution, namely disinfectant raw material solution; and (3) reacting the raw material liquid for 14h at 75 ℃ under a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

3.3 the composition of the iodine and acetic acid of the iodine-containing disinfectant is determined (according to the detection method of the iodine and the carboxylic acid): 3.42 percent of elementary iodine and 8.33 percent of carboxylic acid (calculated as acetic acid).

3.4, performing accelerated test on the disinfectant prepared in the step 3.2 at 80 ℃ for 10 cycles, wherein the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 3.33% and 8.16%, and the change rates are respectively as follows: 2.63 percent and 2.04 percent, which are both less than 5 percent, meet the standard of product stability.

Example 4:

4.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

2% of elemental iodine, 45% of ethanol, 30% of ethyl acetate and 23% of water.

4.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

adding 20g of elemental iodine into 200g of absolute ethyl alcohol, and stirring and dissolving to obtain an A4 solution; mixing 250g of ethanol with 300g of ethyl acetate to obtain a B4 solution; adding the B4 solution into the A4 solution under stirring, fully stirring, adding 230g of water into the mixed solution under stirring to obtain a uniform solution, namely disinfectant raw material solution; and (3) reacting the raw material liquid for 16h at 65 ℃ under a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

4.3 the iodine-containing disinfectant is determined to have the following main component proportion: 1.22 percent of elementary iodine and 8.10 percent of carboxylic acid (calculated by acetic acid)

4.4, performing accelerated test on the disinfectant prepared by the step 4.2 at 80 ℃ for 10 cycles, wherein the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 1.20% and 8.15%, and the change rates are respectively as follows: 1.64 percent and 2.10 percent, which are both less than 5 percent, meet the standard of product stability.

Example 5:

5.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

3.5 percent of elementary iodine, 20 percent of acetic acid, 54 percent of ethyl acetate and 22.5 percent of water.

5.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

taking 300g of ethyl alcohol, adding 35g of elemental iodine, stirring and dissolving to obtain an A5 solution; mixing 200g of acetic acid and 240g of ethyl acetate to obtain a B5 solution; adding the B5 solution into the A5 solution under stirring, fully stirring, and adding 225g of water into the mixed solution under stirring to obtain a uniform solution, namely disinfectant raw material solution; and (3) reacting the raw material liquid for 14h at 75 ℃ under a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

5.3 the iodine-containing disinfectant is determined to have the following main component proportion: 2.41 percent of elemental iodine and 38.4 percent of carboxylic acid (calculated as acetic acid).

5.4, performing accelerated test on the disinfectant prepared in the step 5.2 at 80 ℃ for 10 cycles, wherein the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 2.35% and 37.8%, and the change rates are respectively as follows: 2.49 percent and 1.82 percent, which are both less than 5 percent, meet the standard of product stability.

Example 6:

6.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

8% of elemental iodine, 60% of ethyl acetate and 32% of water.

6.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

taking 600g of ethyl alcohol, adding 80g of elemental iodine, stirring and dissolving to obtain an A6 solution; adding 320g of water into the mixed solution under stirring to obtain disinfectant raw material solution; and (3) reacting the raw material solution for 12h at the temperature of 70 ℃ in a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

6.3 the iodine-containing disinfectant is determined to have the following main component proportion: 4.53 percent of elemental iodine and 26.8 percent of acetic acid.

6.4 the disinfectant prepared by 6.2 is subjected to accelerated test at 80 ℃ for 10 cycles, and the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 4.46 percent and 26.2 percent, and the change rates are respectively as follows: 1.55 percent and 2.24 percent, which are both less than 5 percent, meet the standard of product stability.

Example 7

7.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

2% of elemental iodine, 20% of acetic acid and 78% of water.

7.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

adding 200g of acetic acid into 20g of elemental iodine, stirring and dissolving to obtain an A7 solution; adding 780g of water into the mixed solution under the stirring state to obtain disinfectant raw material solution; and (3) reacting the raw material liquid for 6 hours at the temperature of 100 ℃ in a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

7.3 the composition of the iodine simple substance and the acetic acid of the iodine-containing disinfectant is determined as follows: 1.36 percent of elemental iodine and 21.2 percent of carboxylic acid (calculated as acetic acid).

7.4 the disinfectant prepared in the step 7.2 is subjected to accelerated test at 80 ℃ for 10 cycles, wherein the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 1.33% and 20.7%, and the change rates are respectively as follows: 2.21 percent and 2.50 percent, which are both less than 5 percent, meet the standard of product stability.

Example 8: (pertaining to scheme 2)

8.1 the raw material components for preparing the iodine-containing disinfectant and the dosage thereof are as follows:

15% of citric acid, 5% of elementary iodine, 60% of glycerol and 20% of water.

8.2 taking 1000g of raw material liquid as an example, the preparation method comprises the following steps:

taking 600g of glycerol, adding 50g of elemental iodine, stirring and dissolving to obtain an A8 solution; mixing 150g of citric acid and 200g of water to obtain a B8 solution; adding the B8 solution into the A8 solution under stirring, and fully stirring to obtain a disinfectant raw material solution; and (3) reacting the raw material liquid for 10 hours at the temperature of 85 ℃ in a stirring state, and then standing and cooling to obtain the iodine-containing disinfectant with long-term component stability.

8.3 the composition of the iodine and acetic acid of the iodine-containing disinfectant is determined (according to the detection method of the iodine and the carboxylic acid): 2.90 percent of elementary iodine and 6.4 percent of carboxylic acid (calculated by citric acid).

8.4, performing accelerated test on the disinfectant prepared by 8.2 at 80 ℃ for 10 cycles, wherein the iodine simple substance and the carboxylic acid content of the disinfectant after the accelerated stability test are respectively as follows: 2.88 percent and 6.30 percent, and the change rates are respectively as follows: 0.69 percent and 1.56 percent, which are both less than 5 percent, meet the standard of product stability.

Comparative example 1

The disinfectant was formulated with reference to the composition of example 5 after reaction equilibration. The material after equilibrium reaction of example 5 was analyzed in further detail as: 2.34 percent of iodine, 0.97 percent of iodide (calculated by hydrogen iodide), 0.23 percent of iodic acid (calculated by disproportionation reaction of iodine according to reduction of iodine simple substance and increase of iodine ions), 38.2 percent of acetic acid, 13.8 percent of ethanol, 27.6 percent of ethyl acetate and 17.1 percent of water.

Taking about 1000g of raw material liquid as an example, the preparation method comprises the following steps:

dissolving 23.4g of iodine in a mixed solution of 138g of ethanol and 276g of ethyl acetate, and adding 9.7g of hydrogen iodide (added in the form of 57% hydroiodic acid, wherein the water content is 7.3g, and 17g of hydroiodic acid in total) to obtain an A1-1 solution; 163.7g of water is mixed with 382 g of acetic acid, then 2.3g of iodic acid is added, and the mixture is uniformly mixed to obtain B1-1 solution; and adding the B1-1 solution into the A1-1 solution under stirring to obtain the iodine-containing disinfectant.

It is found that when the preparation is carried out, if the feeding speed is high, a small amount of iodine particles are separated out, and possibly, the hydriodic acid and the iodic acid react to generate an iodine simple substance, so that the iodine simple substance cannot be quickly balanced and/or dissolved under the preparation condition; can generally be redissolved into the system with subsequent stirring.

The iodine-containing disinfectant is determined to have the following main component proportions: 2.65% of elementary iodine and 38.1% of carboxylic acid (calculated as acetic acid).

The prepared disinfectant is subjected to accelerated test for 10 cycles at 80 ℃, and the iodine simple substance and carboxylic acid contents of the disinfectant after the accelerated stability test are respectively as follows: 2.39 percent and 38.9 percent, and the specific change rate of the measurement result during preparation is respectively as follows: 9.81 percent and 2.10 percent. Compared with the originally prepared disinfectant, the content of carboxylic acid in the disinfectant after the accelerated stabilization experiment is not obviously changed and is only slightly increased; but the elemental iodine content became larger, but the value tended to be 2.34% of the equilibrium value. It is possible that a small amount of elemental iodine is formed during formulation, resulting in a larger iodine content at the initial measurement, but is re-consumed and stabilized during subsequent accelerated equilibration.

If the prepared feed liquid is stirred and reacted for 14 hours at the temperature of 75 ℃, the iodine content is measured to be 2.36 percent after cooling. Illustrating that the above feed solution can be finally equilibrated to a result close to that of comparative example 5. However, the raw material hydroiodic acid is dangerous, iodic acid needs to be added, the needed raw materials are increased, elemental iodine can be generated due to the reaction of iodic acid and hydrogen iodide after the hydroiodic acid is added, an equilibrium process is still needed to stabilize the formula finally, although the system can be close to equilibrium as much as possible by means of slow full stirring, control of the feeding sequence and the like, from the aspect of the preparation process, the scheme of directly using iodine as a unique iodine source in the preparation method is obviously more economical for the formula with a certain ratio of iodide and iodic acid compounds in the formula, and the industrial production is easier to realize from the production angle.

The method for measuring the disinfection and sterilization effects of the iodine-containing disinfectant formula specifically refers to the method described in patent application No. CN201010163683.4 (title of the invention: iodine citrate disinfectant and preparation method thereof).

The citric acid iodine disinfectant of the embodiment of the invention has the following sterilization effect:

the experimental results show that: diluting stock solution of disinfectant at 20 deg.C according to iodine content measured during preparation or before hot storage (0 day) with effective iodine content of 100mg/L after dilution, wherein the diluent acts on Escherichia coli and Staphylococcus aureus for 3min respectively, and the sterilization logarithm value is not less than 5.0; diluting stock solution of disinfectant according to iodine content measured in preparation (0 day) with effective iodine content of 500mg/L, wherein the diluted solution acts on Bacillus subtilis black variant spore for 5min, and bactericidal logarithm value is not less than 5.0. And the samples after 10 cycles of heat storage are diluted according to the dilution times in 0 day, and the disinfection and sterilization effects of the samples are almost the same as those of newly prepared samples (0 day).

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not intended to limit the scope of the present invention. All simple and equivalent changes and modifications made according to the claims and the content of the specification of the present application fall within the scope of the claims of the present patent application. The invention has not been described in detail in order to avoid obscuring the invention.