DE102020111417A1 - Aqueous chlorine dioxide solutions and process for making the same - Google Patents

Abstract

The present invention relates to aqueous solutions containing chlorine dioxide, in particular high-purity aqueous chlorine dioxide solutions which can be used, for example, in human and veterinary medicine for disinfecting surfaces, devices and instruments, and to a method for producing such aqueous chlorine dioxide solutions. In particular, the present invention provides a method for preparing an aqueous chlorine dioxide solution, in which a previously prepared aqueous chlorine dioxide solution is treated so that a high-purity aqueous chlorine dioxide solution is obtained. The method according to the invention can be applied to all previously prepared aqueous chlorine dioxide solutions, regardless of the method with which the previously prepared aqueous chlorine dioxide solution has been prepared. By using the method according to the invention, in particular, highly pure aqueous chlorine dioxide solutions can be produced far more simply and cost-effectively from previously produced aqueous chlorine dioxide solutions. It has surprisingly been found that the aqueous chlorine dioxide solutions obtainable with the process according to the invention have a high degree of purity and a surprisingly high stability.

Description

Technical area

The present invention relates to aqueous chlorine dioxide-containing solutions, in particular high-purity aqueous chlorine dioxide solutions which can be used, for example, in the field of human and veterinary medicine for disinfecting surfaces, devices and instruments, as well as a method for producing such aqueous chlorine dioxide solutions. In particular, the present invention provides a method for preparing an aqueous chlorine dioxide solution, in which a previously prepared aqueous chlorine dioxide solution is treated so that a high-purity aqueous chlorine dioxide solution is obtained. The method according to the invention can be applied to all previously prepared aqueous chlorine dioxide solutions, regardless of the method with which the previously prepared aqueous chlorine dioxide solution has been prepared. By using the method according to the invention, in particular high-purity aqueous chlorine dioxide solutions can be produced far more simply and cost-effectively from previously produced aqueous chlorine dioxide solutions. It has surprisingly been found that the aqueous chlorine dioxide solutions obtainable with the process according to the invention have a high purity and a surprisingly high stability.

Background of the invention

Chlorine dioxide and aqueous chlorine dioxide solutions have long been known as very effective bleaching and disinfecting agents and are used on a large scale, for example, as bleaching agents for pulp bleaching (e.g. in paper production) and as disinfectants for disinfecting drinking water. Due to known problems in the production and storage of chlorine dioxide and aqueous solutions containing it (risk of explosion!), The technical production of chlorine dioxide usually takes place immediately before use from chlorate (ClO ₃ ^- ) or chlorite (ClO ₂ ^- ), or the corresponding salts thereof such as the corresponding alkali salts (e.g. sodium chlorate and sodium chlorite). Chlorates, especially sodium chlorate, are used as a cheaper starting material for the production of bleaches on an industrial scale, with sulfur dioxide (Mathieson process) or hydrochloric acid or methanol (Solvay process), for example, being used for chlorate reduction. For applications with higher purity requirements, such as drinking water disinfection, chlorine dioxide is produced from more expensive chlorite, such as sodium chlorite for example hydrochloric acid (hydrochloric acid-chlorite process), a suitable oxidizing agent such as peroxodisulfate (peroxodisulfate-chlorite process) or electric current (chlorite electrolysis process) can be used.

Due to its effectiveness against dangerous pathogens such as bacteria, viruses, protozoa, molds and spores, aqueous chlorine dioxide solutions are also used in human and veterinary medicine as well as general hygiene, such as for the disinfection of surfaces, devices, instruments and the like in doctor's offices, hospitals, laboratories, vehicles, etc. Especially for such applications in the field of medicine, it is necessary that the aqueous chlorine dioxide solutions used are as free of impurities as possible and have sufficient storage stability to enable appropriate storage and logistics. Due to the distribution channels via wholesalers and retailers as well as intermediate storage or stock keeping at the end consumer, storage stability of 18 to 24 months is a basic economic prerequisite. A product that can be realized from an economic point of view particularly requires long-term and stable storage in commercially available packaging without any particular additional effort, such as the need for a continuous cold chain or the like. In addition, particularly for use in the medical field, a high degree of purity of the chlorine dioxide solutions is required in order to avoid undesirable reactions with surfaces to be treated (e.g. corrosion, etc.) or with organic materials present on them (e.g. formation of toxic chlorinated organic compounds, etc.) .ä.), as well as to avoid the formation of possibly harmful residues.

In general, when producing chlorine dioxide and (aqueous) solutions containing chlorine dioxide, the aim is to reduce potentially harmful impurities. In particular, toxic and environmentally harmful impurities should be avoided as completely as possible. For example, when used to disinfect drinking water, the permissible limit value and thus also the permissible manufacturing method are significantly influenced by the (expected) residue of chlorates. In the German Drinking Water Ordinance, the methods permitted for drinking water disinfection and the substances to be used in them are specified in detail. The environmental compatibility of chlorine dioxide products, in turn, depends to a considerable extent on the chlorine they contain, since chlorine, for example, can react with organic compounds to form toxic or otherwise environmentally harmful chlorinated organic compounds. In addition, certain impurities are known to affect the At least promote the corrosiveness of chlorine dioxide products or, in some cases, are responsible for it, such as residues of HCl, which are present, for example, during production using hydrochloric acid. In addition, a particularly pure product is often desirable because it avoids (at least visually) disruptive residues in or on a product treated with chlorine dioxide. As a rule, such residues from use do not come predominantly from the chlorine dioxide itself, but from impurities in its (aqueous) solution, such as salts and the like dissolved therein. Finally, it is also known that impurities can negatively affect the stability of aqueous chlorine dioxide solutions.

Earlier efforts to reduce toxic and environmentally harmful impurities or the resulting reaction products have led to the development of production processes for increasingly pure chlorine dioxide products (see e.g. the modifications of the Mathieson and Solvay processes “Standard Process R2-R10”, for example described in H. Sixta: Handbook of Pulp. VCH-Wiley, Weinheim 2006, pp. 734-777 ; as DE 195 14 612 A1 ; US 2010/0209528 A1 ; Etc.). In addition, different cleaning methods have also been developed (see e.g. GB 760,303 A ; WO 2019/180049 A1 and the publications cited therein). From a chronological point of view, these improvements initially affect the basic manufacturing process, which resulted in fewer and fewer by-products. For example, the R2-R10 standard processes were primarily aimed at minimizing harmful chlorine or chlorate residues. Later, clean manufacturing processes were also combined with cleaning methods that were already known in principle in order to further increase the overall quality.

So describes GB 760,303 A a method for producing aqueous chlorine dioxide solutions, wherein gaseous chlorine dioxide produced in a reaction zone is enriched in an inert gas stream and then the gas stream is passed into water in order to produce an aqueous chlorine dioxide solution. The disadvantage of this process is that undesired gases which are used or are created in the production of the gaseous chlorine dioxide, such as chlorine and / or sulfur dioxide, are also introduced into the chlorine dioxide solution produced and are enriched there. A chlorine dioxide solution produced by this process therefore contains undesired gases, in particular chlorine.

DE 195 14 612 A1 describes a process for producing fresh chlorate-free aqueous chlorine dioxide solutions for disinfecting drinking water by oxidizing sodium chlorite with sodium peroxodisulfate as a chlorine-free oxidizing agent in aqueous solution at a pH between 5.5 and 9.5. In this process, there is no significant formation of chlorate and other undesirable by-products, but the aqueous chlorine dioxide solutions produced in this way contain large amounts of salts such as sulfates and chlorides. These reduce the stability and increase the corrosiveness of the solutions and lead to undesirable residues.

US 2010/0209528 A1 describes a process for making aqueous chlorine dioxide solutions in which dilute chlorine gas is passed through a bed of essentially solid sodium chlorite and then bubbled into water to make chlorine dioxide solutions that are low in sodium chloride. Sodium chloride has according to US 2010/0209528 A1 a negative effect on the stability of aqueous chlorine dioxide solutions. However, the chlorites required for the process are relatively expensive and the chlorine dioxide solutions produced contain chlorine gas, which not only accelerates the decomposition of chlorine dioxide, but can also react with organic compounds to form toxic chlorinated organic compounds. In addition, the use of chlorine gas necessitates considerable safety precautions, which presumably necessitates expensive equipment in (large-scale) practice.

WO 2019/180049 A1 describes a method for producing aqueous chlorine dioxide solutions, in which chlorine dioxide is produced from chlorites using a method known from drinking water disinfection and is introduced into water via an inert gas stream in order to produce an aqueous chlorine dioxide solution. By using suitable chlorine-free oxidizing agents, such as, for example, peroxodisulfate, this process can be used to produce aqueous chlorine dioxide solutions that contain little chlorine and salts. However, this requires relatively expensive chlorite as the starting product, as well as larger quantities of process chemicals and extremely complex equipment.

General problems of these known processes for producing aqueous chlorine dioxide solutions are on the one hand the high costs of the starting materials (in particular chlorites) and on the other hand the achievable purity and the associated shelf life of the products produced therewith. Therefore, there was a need for a production method for storable aqueous chlorine dioxide solutions that can be provided for applications in the medical field.

Description of the invention

The inventor of the present invention has found that storable aqueous chlorine dioxide solutions can be produced inexpensively on a large scale if existing chlorine dioxide solutions - regardless of their original production method - are treated in such a way that a highly pure aqueous chlorine dioxide solution is obtained. In particular, the inventor has found that an aqueous chlorine dioxide solution is particularly stable and therefore storable if particularly impurities in the form of salts and reactive gases are reduced as far as possible in the process, so that the solution has a high degree of purity. It is believed that such impurities accelerate the decomposition of the dissolved chlorine dioxide. Aqueous chlorine dioxide solutions produced according to the present invention have a good shelf life of 18 to 24 months even without cooling.

The present invention thus provides a fundamental solution to the problem of producing high-purity chlorine dioxide solutions by providing a general method for purifying (already present) chlorine dioxide solutions which, regardless of the original production method, is an even further improved end product supplies. The present invention takes the path of first removing the interfering gases by reaction (e.g. by reducing them to ionic compounds) or preventing their formation through intermittent decomposition of chlorine dioxide or other impurities, regardless of the starting product, and then desalinating the intermediate product obtained. In addition to a further improved quality and the associated further improved storage stability, this above all offers considerable economic advantages.

• 1) Bereitstellen einer ersten wässerigen Lösung von Chlordioxid,
• 2) Zugeben einer Reagenz zum Entfernen von unerwünschten Gasen,
• 3) Abtrennen des Chlordioxids von der ersten wässerigen Lösung, und
• 4) Lösen des abgetrennten Chlordioxids in Wasser, um eine gereinigte zweite wässerige Chlordioxid-Lösung zu erhalten.

In particular, the present invention provides a method for preparing an aqueous solution of chlorine dioxide. The method according to the invention comprises the following steps:

• 1) providing a first aqueous solution of chlorine dioxide,
• 2) adding a reagent to remove unwanted gases,
• 3) separating the chlorine dioxide from the first aqueous solution, and
• 4) Dissolve the separated chlorine dioxide in water to obtain a purified second aqueous chlorine dioxide solution.

The method according to the invention can be used according to the invention for treating (cleaning) aqueous chlorine dioxide solutions of any origin - regardless of the original production method of the first aqueous chlorine dioxide solution provided in step (1). As a result, not only chlorite-based processes (or indirect chlorite processes via electrolysis) can be used to produce the first aqueous chlorine dioxide solution, which is provided in step (1), but also the much cheaper chlorate-based processes. Correspondingly, the large-scale systems already available in the paper industry can also be used to produce the first aqueous chlorine dioxide solution provided in step (1). This not only leads to savings of up to 90% in costs, but also offers the possibility of using existing or standardized systems to quickly build up very high capacities worldwide or to quickly scale production if required. This rapid scalability is particularly important in the case of unexpected events with a sudden increase in demand, such as the current Covid-19 pandemic.

In exemplary embodiments of the method according to the invention, the first chlorine dioxide solution can be obtained by reacting a chlorate salt with sulfur dioxide (Mathieson method), by reacting a chlorate salt with hydrochloric acid or methanol (Solvay method), by reacting a chlorite Salt with an acid (acid-chlorite process or acid-hypochlorite-chlorite process), for example hydrochloric acid (hydrochloric acid-chlorite process), by reaction of a chlorite salt with chlorine (chlorine-chlorite process), by reaction from a chlorite salt with sodium peroxodisulfate (peroxodisulfate-chlorite process) or by electrochemical processes (e.g. chlorite electrolysis process or chlorite electrolysis process). The first chlorine dioxide solution is preferably produced from a chlorate salt, particularly preferably sodium chlorate.

The first aqueous chlorine dioxide solution can be provided in step (1) either with a certain volume or continuously. For example, the first chlorine dioxide solution provided in step (1) can be connected via a suitable siphon to a primary production device for chlorine dioxide, so that continuously post-produced chlorine dioxide solution is available as a source for the process according to the invention, which can then be carried out continuously.

For the purposes of the present invention, an aqueous chlorine dioxide solution (sometimes also referred to as an aqueous solution of chlorine dioxide) is a composition which is based on water as a solvent and which comprises chlorine dioxide in dissolved form. Depending on the particular Production process of the first aqueous chlorine dioxide solution, which is provided in step (1) of the process according to the invention, this first chlorine dioxide solution comprises not only chlorine dioxide but also unreacted starting materials, reaction products and / or decomposition products, such as dissolved chlorite ions, hypochlorite ions, chlorate ions, chloride ions, peroxodisulfate ions , Chlorine gas, sulfur dioxide, etc.

The first aqueous chlorine dioxide solution which is provided in step (1) preferably comprises chlorine dioxide in a concentration of 2000 to 6500 ppm (unless stated further, the specification ppm refers to parts by weight), more preferably from 4000 to 5500 ppm, and particularly preferably from about 5000 ppm.

In step (2) of the method according to the invention, undesired reactive gases are removed from the chlorine dioxide solution, in particular the reactive gases chlorine and / or sulfur dioxide that were used in the production of the first chlorine dioxide solution provided in step (1) or are formed therein can. For this purpose, a suitable chlorine dioxide-stable reactant (the reagent) is added to the first chlorine dioxide solution provided in step (1), with which such reactive gases can be removed from the solution. In the context of the present invention, the expression “removal of undesired gases” is used to denote a chemical reaction by which a gas dissolved in the aqueous solution is chemically bound in such a way that it can no longer escape from the solution in gaseous form. For example, a dissolved gas is chemically bound by reacting with the reagent to form corresponding dissolved ionic compounds. For example, a gas can be oxidized or reduced, or converted into a larger (ionic) molecule through an addition reaction. In any case, the addition of the reagent for removing undesired gases and the subsequent reaction with the dissolved gas prevents a gas from escaping from the solution. The inventive removal or chemical conversion of the interfering gases by reaction with the reagent in the aqueous solution has the advantage over other methods that are based, for example, on reactions in the gas phase, that a rapid and complete removal of the undesired gases from the aqueous solution is less controllable reaction conditions takes place.

Hydrogen peroxide and carbonates, bicarbonates, chlorites and hydroxides, preferably in the form of their alkali or alkaline earth salts, particularly preferably sodium carbonate, sodium bicarbonate, sodium chlorite and sodium hydroxide, are suitable as reagents for removing undesired gases. In the process according to the invention, sodium carbonate is very particularly preferably used as the reagent for removing undesired salts, preferably in the form of buffered sodium carbonate.

The reagent used in step (2) to remove undesired gases is preferably added in a suitable (aqueous) solution, but can also be added in solid form (e.g. in salt form). In an aqueous solution, the dosage is both easier and the reaction faster or less or no additional mixing is required.

The reagent for removing undesired gases is preferably added in amounts which are sufficient to remove all gases present in the first chlorine dioxide solution. For example, the reagent is added in excess, preferably in a molar ratio of reagent to chlorine of 1.1: 1 to 5: 1, preferably 1.5: 1 to 2: 1. If the chlorine content is unknown, the reagent is added in a molar ratio of reagent to chlorine dioxide of 0.1: 1 to 2: 1, preferably in a molar ratio of 0.5: 1 to 1.5: 1, depending on the manufacturing process. Aqueous chlorine dioxide solutions that have been produced according to more recent processes or processes known as “cleaner” in the prior art require a smaller amount of reagent than those from older processes or processes known as less “clean”.

In a preferred embodiment of the method according to the invention, before the addition of the reagent for removing undesired gases in step (2), the pH of the first solution provided in step (1) is adjusted to a slightly acidic to neutral pH of 4.0 to 7.5 adjusted, particularly preferably to a neutral pH, preferably in the range from 6.5 to 7.5. The neutral pH value is more preferably a pH value in the range from 6.8 to 7.2 and the neutral pH value is particularly preferably approximately 7.0. The neutral pH is preferably stabilized by adding a buffer system. Suitable buffer systems and methods for establishing a neutral pH are known in the art. The buffer system is preferably selected from a carbonate buffer system, a phosphate buffer system and a peroxodisulfate buffer system.

By setting a neutral pH value for the first aqueous chlorine dioxide solution provided in step (1), the new formation of undesired gases, in particular chlorine gas, through any acid or base-mediated reactions (such as the decomposition of chlorine dioxide) is effectively prevented .

Because sodium carbonate is used both as a reagent to remove unwanted gases and to create a carbonate buffer system can be used, in a particularly preferred embodiment of the method according to the invention, the pH of the first solution provided in step (1) can be adjusted to a neutral value by adding the reagent for removing undesired gases in step 2). This special embodiment of the method according to the invention can be used in particular when the first chlorine dioxide solution provided in step (1) is an acidic solution (pH <6.5). Since all known manufacturing processes for chlorine dioxide take place in the acidic range, an acidic solution will usually be present.

In step (3) of the process according to the invention, the chlorine dioxide is then separated off from the chlorine dioxide solution which has been purified from undesired gases in step (2). In principle, the chlorine dioxide can be separated off from the chlorine dioxide solution which has been purified from undesired gases in step (2) using any method known in the art. The chlorine dioxide is preferably separated from the aqueous solution in step 3) in the gaseous state, for example by contacting with a carrier gas stream (so-called "stripping" process) or by distilling under reduced pressure (so-called "sub-boiling" distillation) .

Methods and devices for separating chlorine dioxide with a carrier gas stream (“stripping” method) are, for example, off GB 760,303 A and WO 2019/180049 A1 known. In general, in these known methods, a suitable carrier gas is brought into contact with an (aqueous) chlorine dioxide solution, so that chlorine dioxide accumulates in gaseous form in the carrier gas. The chlorine dioxide / carrier gas mixture is then moved away from the first solution via appropriate lines, pumps, etc. and subsequently brought into contact with water, for example, in order to produce a second aqueous chlorine dioxide solution.

Correspondingly, in a preferred embodiment of the method according to the invention, the chlorine dioxide solution which has been purified from undesired gases in step (2) is brought into contact with a suitable carrier gas. To bring it into contact, the carrier gas can, for example, be passed over the surface of the chlorine dioxide solution or blown through the chlorine dioxide solution using suitable nozzles in order to enrich the chlorine dioxide more quickly in the carrier gas. The carrier gas enriched with chlorine dioxide is then spatially separated from the remaining aqueous solution using suitable lines, pumps, etc.

The carrier gas used is preferably a carrier gas that is inert to chlorine dioxide, such as, for example, air, nitrogen, carbon dioxide, oxygen, a noble gas such as, for example, argon, and mixtures thereof. The carrier gas is preferably selected from nitrogen, carbon dioxide and argon. The preferred flow rate of carrier gas is related to the amount of chlorine dioxide solution. The carrier gas is preferably blown at a flow rate of 0.01 to 1% of the volume of the chlorine dioxide solution per minute over the surface of the chlorine dioxide solution cleaned of undesired gases in step (2) or at a flow rate of 0.1% to 10% of the volume of the chlorine dioxide solution per minute blown through the chlorine dioxide solution cleaned of undesired gases in step (2). For example, for a volume of 1000 liters of chlorine dioxide solution, the flow rate of an air stream is 1 to 100 liters per minute, preferably 5 to 10 liters per minute.

In an alternative embodiment of the process according to the invention, the chlorine dioxide is separated from the chlorine dioxide solution which has been purified from undesired gases in step (2) by distillation under reduced pressure (so-called “sub-boiling” distillation). The process according to the invention enables sensible distillation by first removing all interfering gases from the chlorine dioxide-containing solution in step (2).

Presumably due to the low decomposition point (from 45 ° C), the theoretical risk of explosion and the possibility of displacing chlorine dioxide from aqueous solution with other gases (“stripping”), aqueous chlorine dioxide solutions are not purified by distillation in current commercial processes.

The inventor of the present invention has found that a distillation of chlorine dioxide from an aqueous solution can be carried out safely if the distillation temperature is reduced to well below 45 ° C. by lowering the pressure. Under correspondingly reduced pressure conditions, chlorine dioxide can thus be separated from the chlorine dioxide solution, which has been purified from undesired gases in step (2), by distillation under reduced pressure, without product decomposition or explosion.

The pressure is preferably reduced to such an extent that the distillation is carried out at a temperature of 35 ° C or less, more preferably at room temperature (e.g. a temperature of 20 to 25 ° C) or a temperature of 20 ° C or 25 ° C (standard Room temperature). External influences, such as energy input, hotspots, light irradiation, etc., are excluded as far as possible.

For laboratory use (= maximum purity of the end product with small production quantities) a temperature-pressure combination is selected at which the water does not yet boil significantly, for example more than 30 mbar at 20 ° C or more than 40 mbar at 25 ° C.

For technical applications (= larger production quantities with a higher tolerance for impurities), a temperature-pressure combination is selected to increase process reliability at which the water also boils, for example 23 mbar at 20 ° C or 32 mbar at 25 ° C. More preferably, the boiling point of the water has not yet been reached, so that there is no significant bubble formation with even higher impurities caused by this, for example 24 mbar at 20 ° C. or 33 mbar at 25 ° C. Due to the (almost) boiling of the water, certain impurities are accepted, on the other hand, the water-chlorine dioxide mixture ensures that the chlorine dioxide concentration does not exceed 10% at any time and therefore that there is no theoretical risk of explosion at any time. Since in this embodiment a significantly larger amount of distillate arrives in the collecting container due to the distilled water, a greater temperature difference between the output container and the collecting container and / or cooling of the collecting container is desirable in this embodiment.

To increase the purity, several distillation steps can take place one after the other, the distillation can be carried out via a cascade of several water containers or the distillation can be repeated one or more times.

In a further preferred embodiment of the process according to the invention, distillation is carried out under reduced pressure in combination with a stream of carrier gas being blown through the chlorine dioxide solution which has been purified from undesired gases in step (2). This combination of “sub-boiling” distillation and “stripping” processes enables chlorine dioxide to be separated particularly quickly from the chlorine dioxide solution that has been cleaned of undesired gases in step (2).

In all embodiments, additional (chemical) filters can preferably be used to increase the purity in the distillation stream between the containers, such as solid NaClO ₂ as a chemical chlorine filter or chlorine dioxide-resistant particle filters as salt filters, for example HEPA / ULPA filters made of PTFE.

The chlorine dioxide separated off in step (3) is redissolved in water in step (4) to produce a purified second aqueous chlorine dioxide solution. The water in which the chlorine dioxide separated off in step (3) is dissolved is preferably pure water, for example distilled water or water completely desalinated by osmosis (deionized water).

Preferably, the pH of the water can be adjusted to a neutral value (preferably a pH of 6.5 to 7.5, more preferably from 6.8 to 7.2, and particularly preferably about 7.0) with a suitable buffer system (preferably a carbonate, phosphate or peroxodisulfate buffer system). Accordingly, the second aqueous chlorine dioxide solution produced contains not only water and chlorine dioxide but also the respective buffer system.

In particular for use as a disinfectant, the second aqueous chlorine dioxide solution produced can also comprise one or more suitable, chlorine dioxide-stable surfactants. Suitable surfactants or surfactant combinations include, for example, quaternary ammonium compounds and / or non-ionic surfactants, preferably carboxylic acid esters and / or phosphate esters, such as, in particular, ethoxylated aliphatic phosphate esters or phosphate diesters and / or ethoxylated carboxylic acid esters, preferably aliphatic carboxylic acid esters and / or alkyl ethers Phosphates, as well as ethoxylated fatty alcohols, ethoxylated fatty amines, ethoxylated alkylphenols, and / or ethoxylated fatty acids. A chlorine dioxide solution according to the invention preferably contains a surfactant or a surfactant combination in a concentration of 10% by weight or less, more preferably in a concentration of 5% by weight or less, and particularly preferably in a concentration of 10% by weight. % Or less.

In a preferred embodiment, the surfactant is contained in the aqueous collecting solution from the start, since it promotes the absorption of the chlorine dioxide gas or minimizes its renewed stripping by the gas flow from the collecting container to the vacuum pump or to the gas outlet.

In a preferred embodiment of the process according to the invention, the water in which the chlorine dioxide separated off in step (3) is dissolved is cooled to a temperature of less than 20 ° C., preferably to a temperature of less than 10 ° C.

If the chlorine dioxide is separated off with the aid of a carrier gas stream in step (3), the carrier gas / chlorine dioxide mixture can preferably be introduced into the (preferably cooled) water using suitable nozzles and distributed therein in order to dissolve the chlorine dioxide more quickly in the water. Devices and methods suitable for this are, for example, from GB 760,303 A and WO 2019/180049 A1 known.

If the chlorine dioxide is separated in step (3) by distillation under reduced pressure, the chlorine dioxide for condensation can be introduced directly into the (preferably cooled, eg to 10 ° C. or less) water and thus dissolved therein. The distillation process represents a particularly preferred embodiment of the process according to the invention, since it offers the further advantage over the likewise possible carrier gas flow process, for example, that no gas flow has to be passed through the water. A flow through the manufactured product is always associated with the risk that the outflowing carrier gas flow in turn entrains chlorine dioxide from the product solution and thus leads to a reduced chlorine dioxide concentration in the product and the associated losses and costs.

In an exemplary preferred embodiment of the method according to the invention, a first aqueous chlorine dioxide solution is provided in a first step, which was prepared from chlorate, for example by reacting sodium chlorate with hydrochloric acid. The pH of this first aqueous chlorine dioxide solution is adjusted to a neutral value in the range from 6.5 to 7.5 and sodium carbonate is added in order to remove dissolved chlorine gas from the solution or to bind it chemically. Then the chlorine dioxide is distilled off under reduced pressure and dissolved in (pure) water to produce a purified second aqueous chlorine dioxide solution.

In summary, the present invention provides a method for producing a high-purity aqueous chlorine dioxide solution, in which existing large-scale plants and methods can be used to produce an inexpensive first aqueous chlorine dioxide solution in large quantities, which is then purified by the method according to the invention that it is suitable, for example, for applications in the medical field. In particular, by using cheap starting materials such as NaClO ₄ , HCl, NaCO ₃ , etc., the costs can be reduced by 75 to 90% compared to other processes. In addition, the method according to the invention does not require the use of hazardous chemicals, such as, for example, chlorine gas or the like, which also makes it easier to carry out and reduces costs compared with other methods.

In particular, the inventive removal of the interfering gases by reaction in aqueous solution has the advantage over other methods based, for example, on reactions in the gas phase, that the undesired gases are removed quickly and completely under controllable reaction conditions. The process according to the invention thus reliably produces chlorine-free chlorine dioxide solutions which are suitable, for example, for applications in the medical field. The separation of the chlorine dioxide from the aqueous solution previously purified from undesired gases, in particular chlorine and sulfur dioxide, which is particularly preferably carried out by distillation under reduced pressure, and the subsequent dissolution in (pure) water reliably leads to an aqueous chlorine dioxide solution, which does not contain unwanted salts. Chlorates, for example, are undesirable because the chlorine dioxide content is usually determined as chlorate. The content of cations, such as sodium ions, and anions, such as chloride ions, is also advantageously low.

The total content of impurities in the aqueous chlorine dioxide solution produced by the process according to the invention is preferably less than 1000 ppm, more preferably less than 500 ppm, and particularly preferably less than 100 ppm.

Depending on the intended application, an aqueous chlorine dioxide solution produced according to the invention has a chlorine dioxide concentration of at least 100 ppm. Such a chlorine dioxide solution can be used directly without a concentrate having to be prepared and diluted beforehand. The present invention also enables the manufacture of concentrates. Concentrates preferably have a chlorine dioxide concentration of at least 1500 ppm, more preferably of at least 2000 ppm. The total content of all impurities (gases and salts) is preferably less than 1000 ppm, more preferably less than 100 ppm. Preferably, both the chlorine content and the chlorate content and the sodium content are each less than 100 ppm, and particularly preferably the total chlorine, chlorate and sodium content is less than 100 ppm.

A chlorine dioxide solution prepared according to the invention preferably retains more than 90% of the original concentration of chlorine dioxide for at least 18 months when stored at room temperature (15 to 25 ° C.). In particular, a chlorine dioxide solution prepared according to the invention retains more than 95% of the original concentration of chlorine dioxide when stored at room temperature (15 to 25 ° C.) for at least 24 months.

The inventively produced chlorine dioxide solutions are preferably packaged in suitable containers, for example in glass bottles with (poly) fluoroelastomers or PVC coated closures or caps, made of or containing (poly) fluoroelastomers, such as in particular PTFE, PEEK, Viton ^®, or a PTFE-polymer mixture. Alternatively, plastic bottles made from the polymers mentioned can also be used will. Packaging preferably offers protection against light radiation and other external influences, such as rapid temperature fluctuations, shocks or the like. For example, a packaging can be an opaque container (for example a dark glass bottle or the like). In a preferred embodiment, the chlorine dioxide solutions produced according to the invention are packaged in shipping units of 4 or 6 glass bottles in a suitably dimensioned styrofoam box so that they are protected against light as well as against shocks and rapid temperature fluctuations.

The present invention additionally also provides a disinfectant based on the chlorine dioxide solution prepared according to the invention. This is produced by adding at least one suitable, chlorine dioxide-stable surfactant to the chlorine dioxide solution prepared according to the invention, such as a quaternary ammonium compound and / or a non-ionic surfactant, preferably carboxylic acid esters and / or phosphate esters such as, in particular, ethoxylated aliphatic phosphate esters or Phosphate diesters and / or ethoxylated carboxylic acid esters, preferably aliphatic carboxylic acid esters and / or alkyl ether phosphates, as well as ethoxylated fatty alcohols, ethoxylated fatty amines, ethoxylated alkylphenols and / or ethoxylated fatty acids. A surfactant or a surfactant combination is preferably added to the chlorine dioxide solution according to the invention in a concentration of 10% by weight or less, more preferably in a concentration of 5% by weight or less, and particularly preferably in a concentration of 10% by weight. -% Or less.

The chlorine dioxide solutions produced by the process according to the invention are preferably used for surface disinfection and as medical products and in human and veterinary medicine. When applied superficially, hardly any or only negligible residues are left behind. Finally, it offers significant advantages in medical use, be it as a drug or as a medical product, since no impurities can influence the effect, which means that it can be defined much more clearly. This leads, among other things, to lower use quantities / concentrations or fewer side effects.

A chlorine dioxide solution according to the invention can preferably be used, for example, to disinfect solid surfaces or water, in particular to remove bacteria, viruses, protozoa, molds and / or spores from these surfaces or water. An application in the human or veterinary medical field can also relate to the treatment of skin, nails, hooves, claws, wounds, etc. Furthermore, a chlorine dioxide solution according to the invention can also be used for disinfecting food.

Particularly preferred is the use of the pH-neutral chlorine dioxide solution according to the invention, which contains one of the surfactants disclosed in a concentration of less than 500ppm, more preferably less than 150ppm, since this solution surprisingly proved to be particularly skin-friendly due to the low residues and the selected surfactant Has.

Examples

The method according to the invention is described below in connection with exemplary embodiments.

example 1

The pH value of an aqueous chlorine dioxide solution (1.0 liter with a chlorine dioxide concentration of 5000 ppm and a pH value of 2.0) prepared by reacting sodium chlorate with hydrochloric acid according to the industrial process for bleaching agents is determined by adding an aqueous Solution of 5.0 wt .-% sodium carbonate and 2.0 wt .-% sodium hydrogen sulfate as a buffer adjusted to 7.0 in order to bind chlorine gas dissolved in the solution. Then the chlorine dioxide is distilled off at room temperature (about 20 ° C) and a pressure of 40 mbar and dissolved directly in 1.0 liter of distilled water (deionized water), which is cooled to 10 ° C, up to a concentration of 2000 ppm .

The aqueous chlorine dioxide solution produced in this way is packed in glass bottles with a stopper made of a PTFE-polymer mixture, and the bottles are again light-tight in shock-absorbing styrofoam packaging. After storage at room temperature for 18 months, the chlorine dioxide solution has a concentration of 1860 ppm (93% of the initial concentration) and after 24 months a concentration of 1820 ppm (91% of the initial concentration).

Example 2

To produce a disinfectant solution containing chlorine dioxide, chlorine dioxide is distilled off as in Example 1, but then at 10 ° C in 1.0 liter of distilled water, which is mixed with a carbonate / phosphate buffer (sodium carbonate (soda) and phosphoric acid, each approx. 01 mol) is set to a pH value of 7.0 and contains a surfactant (“Dehyton AB 30” from BASF) in a concentration of 2 g / l, dissolved up to a concentration of 2000 ppm.

The aqueous disinfectant solution containing chlorine dioxide prepared in this way is used in Glass bottles that are closed with a stopper made of a PTFE polymer are packed, and the bottles are in turn light-tight in shock-absorbing styrofoam packaging.

After storage at room temperature for 18 months, the disinfectant solution has a chlorine dioxide concentration of 1900 ppm (95% of the initial concentration) and a chlorine dioxide concentration of 1860 ppm after 24 months (93% of the initial concentration).

QUOTES INCLUDED IN THE DESCRIPTION

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Patent literature cited

• DE 19514612 A1 [0005, 0007]
• US 2010/0209528 A1 [0005, 0008]
• GB 760303 A [0005, 0006, 0027, 0044]
• WO 2019/180049 A1 [0005, 0009, 0027, 0044]

Non-patent literature cited

• the modifications of the Mathieson and Solvay processes "Standard Process R2-R10", e.g. described in H. Sixta: Handbook of Pulp. VCH-Wiley, Weinheim 2006, pp. 734-777 [0005]

Claims (15)

A method for preparing an aqueous solution of chlorine dioxide comprising the steps of: 1) providing a first aqueous solution of chlorine dioxide, 2) adding a reagent to remove unwanted gases, 3) separating the chlorine dioxide from the first aqueous solution, and 4) Dissolve the separated chlorine dioxide in water to obtain a purified second aqueous chlorine dioxide solution. Procedure according to Claim 1 , the reagent for removing undesired gases being selected from hydrogen peroxide and carbonates, bicarbonates, chlorites and hydroxides, preferably in the form of their alkali or alkaline earth metal salts, preferably sodium carbonate, sodium bicarbonate, sodium chlorite and sodium hydroxide, and particularly preferably sodium carbonate. Procedure according to Claim 1 or 2 , the pH of the first solution being adjusted to a neutral value before the reagent for removing undesired gases is added in step 2). Method according to one of the preceding claims, wherein the pH of the first solution is adjusted to a neutral value by adding the reagent for removing undesired gases in step 2). A method according to any preceding claim, wherein the neutral pH is a pH in the range from 6.5 to 7.5. Method according to one of the preceding claims, wherein the neutral pH is stabilized by adding a buffer system, preferably selected from a carbonate buffer system, a phosphate buffer system and a peroxodisulfate buffer system. Method according to one of the preceding claims, wherein the separation of the chlorine dioxide from the aqueous solution in step 3) is carried out by contacting with a carrier gas stream, preferably using an inert carrier gas, preferably selected from nitrogen, carbon dioxide and argon. Process according to one of the preceding claims, wherein the separation of the chlorine dioxide from the aqueous solution in step 3) is carried out by distillation under reduced pressure, preferably at a temperature of 35 ° C or less. Method according to one of the preceding claims, wherein the water in which the chlorine dioxide is dissolved in step 4) is cooled, preferably to a temperature of less than 20 ° C. Method according to one of the preceding claims, wherein the water in which the chlorine dioxide is dissolved in step 4) has a neutral pH value in the range from 6.5 to 7.5 and / or comprises a surfactant. Method according to one of the preceding claims, wherein the first aqueous solution of chlorine dioxide by reaction of a chlorate salt with sulfur dioxide, by reaction of a chlorate salt with hydrochloric acid or methanol, by reaction of a chlorite salt with an acid, in particular hydrochloric acid, by reaction of a chlorite salt with chlorine, by reaction of a chlorite salt with sodium peroxodisulfate or by electrochemical processes. Method according to one of the preceding claims, which is carried out continuously, in particular wherein the first aqueous solution of chlorine dioxide is provided continuously. Aqueous chlorine dioxide solution, obtainable by the process according to one of the preceding claims. Aqueous chlorine dioxide solution after Claim 13 , characterized by a total content of impurities of less than 1000 ppm and / or characterized by a chlorine dioxide concentration of at least 2000 ppm and / or characterized by stability of more than 90% of the original concentration of chlorine dioxide for at least 18 months at 15 to 25 ° C. Use of an aqueous chlorine dioxide solution according to one of the Claims 13 or 14th to disinfect, preferably from solid surfaces or water, preferably to remove bacteria, viruses, protozoa, molds and / or spores from these surfaces or water.