TR2022008352T2 - METHOD AND SYSTEM FOR SELF-INDUCED SEPARATION OF FLUORE AND CHLORINE - Google Patents

Abstract

A method for the self-induced separation of fluorine and chlorine includes the following steps: 1) obtaining a saturated chlorine-containing solution: adding chlorine to the fluoro-chlorinated wastewater to increase the concentration of chloride ions in the fluoro-chlorinated wastewater until the chloride ions become supersaturated and fluoro-chlorinated. Crystallization and precipitation of all fluoride ions and some chloride ions in the wastewater to obtain chlorine mixture crystals, the liquid phase is the saturated chlorine-containing solution; 2) obtaining a chloride crystal salt: crystallizing the saturated chlorine-containing solution obtained in step 1) to obtain the chloride crystal salt; and 3) obtaining fluoride crystals by separation: dissolving the fluoride-chlorine mixture crystals obtained in step 1) to obtain a fluorine-chlorine mixed solution and obtaining fluoride crystals by separation by multiple dissolutions and addition of fluoride. Also described is a system for the self-induced separation of fluorine and chlorine. The processing method and system for separating fluorine and chlorine can reduce the use of auxiliary additives and effectively and accurately separate fluorine elements from chlorine elements, thus improving the removal quality and purity of fluorinated-chlorinated wastewater.

Description

DESCRIPTION METHOD AND SYSTEM FOR THE SELF-INDUCED SEPARATION OF FLUORE AND CHLORINE The present application claims priority, which was filed with the National Intellectual Property Administration of China on June 30, 2020, and is incorporated herein by reference in its entirety. TECHNICAL FIELD The present invention relates to a method for the separation of hydrochloric acid and chlorine, and specifically to a method for the self-induced separation of hydrochloric acid and chlorine, which belongs to the technical field of treating sintering wastewater. Furthermore, the present invention relates to a system for the self-induced separation of water and chlorine. BACKGROUND ART Large amounts of chlorinated high-salt wastewater are produced from the metallurgical, chemical and pharmaceutical industries. If fluorinated-chlorinated high-salt wastewater is discharged directly without being treated, it causes ecological destruction and threatens human health such as dental fluorosis and other diseases. Generally, Ilor-chlorinated wastewater is treated by methods such as precipitation, adsorption, ion exchange, electrodialysis and chemical Iloculent precipitation, thus converting Ilor into other forms to ensure the removal of Ilor and the remaining chlorine-containing wastewater is discharged or converted into crystalline salts. These methods have different advantages and disadvantages and conditions of use. In general, these methods have disadvantages such as complex operation, high investment and low resource usage. 38761.07 As an important chemical raw material, sodium/potassium chloride is widely used in the chemical industry, metallurgy, wood preservatives and the like. At present, the main production methods of sodium/potassium Iloride include melt impregnation method, neutralization method, sodium Ilorosilicate method, ion exchange method, etc. There are. However, all these methods require a high Iloride ion concentration, typically a higher concentration than that in wastewater containing actual Iloride. Therefore, in current technology, wastewater containing Ilor cannot generally be used to prepare and recycle sodium Ilor. The method of using laureate wastewater to prepare and recycle Sodium Iloride is stated only in the numbered Chinese patent document, where it is stated that Ilorine is separated from Ilorine-containing wastewater by adding a precipitant containing calcium, a precipitant containing magnesium, a precipitant containing sodium, a precipitant containing ammonium or ammonia to the wastewater. . However, this method has disadvantages such as large amount of chemical addition, complex process, and therefore needs to be further developed. Therefore, how to provide a method for the self-induced separation of Ilor and chlorine is a technical problem that needs to be urgently solved by those skilled in the art, which can reduce the use of auxiliary additives in the treatment process of Ilor and chlorine to improve the sanitation of Ilor and chlorine wastewater treatment; It can effectively and accurately separate the elements chlorine and chlorine to improve the processing quality of chlorinated and chlorinated wastewater. BRIEF DESCRIPTION OF THE INVENTION In light of the shortcomings in the existing technology described above, the object of the present invention 38761.07 is to improve the sanitation of chlorinated-chlorinated wastewater treatment by not including any other impurities in the chlorinated-chlorinated wastewater treatment process and to effectively remove the elements chlorine and chlorine in order to improve the quality of chlorinated-chlorinated wastewater treatment. and separate it correctly. The present invention realizes a method for the self-induced separation of chlorine and chlorine, the method comprising the following steps: l) obtaining a saturated chlorine-containing solution: to increase the concentration of chloride ions in fluoride-chlorinated waste water until the chloride ions become supersaturated. subjecting the water to the process of adding chlorine, so that all the chloride ions and some of the chloride ions in the wastewater are crystallized to obtain a mixture crystal of chlorine and chlorine, and the liquid phase is a saturated chlorine-containing solution; 2) obtaining a chloride crystalline salt: subjecting the saturated chlorine-containing solution obtained in step 1) to a crystallization process to obtain a chloride crystalline salt; and 3) separating to obtain a Iloride crystal: Dissolving and repeatedly dissolving the Iloride and chlorine mixture crystal obtained in step 1) to obtain a mixed solution containing Iloride and chlorine, and externally adding Iloride to obtain a Iloride crystal. separation According to a first embodiment of the present invention, a method for the self-induced separation of chlorine and chlorine is provided. A method for the self-induced separation of fluorine and chlorine includes the following steps: l) obtaining a saturated chlorine-containing solution: Subjecting the fluoro-chlorinated wastewater to chlorine addition to increase the concentration of chloride ions in the fluoride-chlorinated wastewater until the chloride ions become supersaturated. Thus, all the chloride ions and some of the chloride ions in the wastewater are crystallized to obtain a mixture crystal of chloride and chloride, and the liquid phase is a saturated chlorine-containing solution; 2) obtaining a chloride crystalline salt: subjecting the saturated chlorine-containing solution obtained in step 1) to a crystallization process to obtain a chloride crystalline salt 38761.07; and 3) separating to obtain a Iloride crystal: Dissolving and repeatedly dissolving the Iloride and chlorine mixture crystal obtained in step 1) to obtain a mixed solution containing Iloride and chlorine, and externally adding Iloride to obtain a Iloride crystal. separation In the present invention, a mixed solution containing Ilor and chlorine is obtained by dissolving the Ilor and chlorine mixture crystal obtained in step 3), step 1). The concentration of fluoride ions in the mixed solution containing fluoride and chlorine is increased until the fluoride ions become supersaturated and the chloride ions are crystallized to obtain a chloride crystal. The purpose of repeatedly dissolving and adding fluoride externally is to reduce the concentration of fluoride ions in the mixed solution containing chlorine and chloride until the fluoride ions become supersaturated. Dissolution times are such that the concentration of Iloride ions in the mixed solution containing Ilor and chlorine reaches until the Iloride ions reach supersaturation. Preferably, in step 3), the concentration of Iloride ions in the mixed solution containing Iloride and chlorine is achieved by specifically adding a water-soluble Iloride salt to the mixed solution containing Iloride and chlorine until the Iloride ions become supersaturated, until the added Iloride salt is no longer dissolved. Preferably, the water-soluble Iloride salt is the Iloride crystal obtained in step 3. Preferably the water-soluble Iloride salt is commercially available Iloride. Preferably, in step 1), increasing the concentration of chloride ions in the water until the chloride ions become supersaturated is specifically accomplished by: adding a water-soluble chloride to the water-chlorinated waste water until the chloride addition completion conditions are met and the chloride addition process is completed. addition of salt, where the conditions for completing the chloride addition are the insolubility of the added chloride crystal salt or the concentration of chloride ions in the chlorinated wastewater as CF, CF<0.1 g/L, preferably CF<0.05 g/L; and more preferably CF<0.01 g/L. Preferably, the water-soluble chloride salt is the chloride crystalline salt obtained in step 2). Preferably the water-soluble chloride salt is commercially available chloride. Preferably, the method also includes the following steps: 4) After the chloride ions are crystallized to obtain a chloride crystal with a chloride and chloride mixed solution as the liquid phase in step 3), the chloride ions in the high chlorine and high chloride mixed solution obtained in step 3) determining the concentration of chloride ions, Cci; if the high chlorine mixed solution is included in the chlorinated-chlorinated wastewater in step 1), otherwise, the high chlorinated and high chlorinated mixed solution is included in step 3) as a dissolving mother liquor. Preferably, in step 1) and step 3), one or more centrifugal separation, gravity sedimentation and filtration separation methods are used for solid-liquid separation. Preferably, the crystallization process in step 2) is one or more forms 38761.07 of evaporative crystallization, refrigeration crystallization, and freeze-drying crystallization. Preferably, chlorinated wastewater is a water-soluble chloride salt or wastewater containing a chloride salt, or a mixture of wastewater containing a water-soluble chloride salt and wastewater containing a water-soluble chloride salt. Preferably, the high saline wastewater is one or more selected from wastewater containing sodium chloride and sodium chloride, wastewater containing potassium chloride and potassium chloride, and wastewater containing ammonium chloride and ammonium chloride. Preferably, the concentration of chloride ions in the chlorinated wastewater is 0.05 g/L-15 g/L and the concentration of chloride ions is 0.01 g/L-150 g/L. According to a second embodiment of the present invention, a system for the self-induced separation of chlorine and chlorine is provided. The system for the self-induced separation of chlorine and chlorine using the method described in the first embodiment of the present invention includes a chlorine addition and salt precipitation apparatus, a mixing and dissolving and precipitation apparatus, and a solution crystallization apparatus. A chlorinated wastewater pipeline is connected to a liquid inlet of the chlorine addition and salt precipitation apparatus. A feed inlet of the chlorine addition and salt precipitation apparatus is connected to a chloride source. A liquid outlet of the chlorine addition and salt precipitation apparatus is connected to a liquid inlet of the solution crystallization apparatus. A chloride crystalline salt solution is discharged from a solid outlet of the crystallization apparatus. A solids outlet of the chlorine addition and salt precipitation apparatus is connected to a feed inlet of the mixing and dissolving and precipitation apparatus. 38761.07 A feed inlet of the mixing and dissolving and settling apparatus is connected to a source of chloride. A chloride crystalline salt is discharged from a solid outlet of the mixing and dissolving and precipitating apparatus. Preferably, the chloride source to be supplied to the feed inlet of the chloride addition and salt precipitation apparatus is the chloride crystalline salt discharged from the solution crystallization apparatus. Preferably, a liquid outlet of the mixing, dissolving and settling apparatus is connected back to the feed inlet of the mixing, dissolving and settling apparatus via a first high Ilor circulation pipeline; or it is connected to the chlorine addition and salt precipitation apparatus via a second high Ilor circulation pipeline. Preferably, a chloride ion concentration sensor is arranged at the liquid outlet of the mixing and dissolving and settling apparatus. In the first embodiment of this application, a method for the self-induced separation of chlorine and chlorine is realized, which is used to treat chlorinated wastewater to obtain chloride crystals and chloride crystalline salts. Specifically, the chloride-chlorinated wastewater is first subjected to a chlorine addition process to increase the concentration of chloride ions in the chloride-chlorinated wastewater until the chloride ions become saturated. Due to the common ion effect, that is, the higher the concentration of chloride 38761.07 ions in the solution, the lower the solubility of chloride ions, chloride ions will be preferentially precipitated; When the concentration of chloride ions in the solution is supersaturated, chloride ions will partially precipitate while chloride ions will be completely precipitated; At the end of step l), a saturated chlorine-containing solution and a crystal of chlorine and chlorine mixture are obtained. In step 2), a chloride crystalline salt is precipitated from the saturated chlorine-containing solution by the crystallization process. Finally, in step 3), the Ilor-chlorine mixture is dissolved and then subjected to a Ilor addition process to increase the concentration of Iloride ions in the mixed solution containing Ilor and chlorine until supersaturation. Similarly, according to the common ion effect, Iloride ions are preferentially precipitated in the form of Iloride crystals and thus Iloride crystals are obtained. According to the technical solution provided by this application, no other impurities are added in the process of treating chlorine-chlorinated wastewater, thus improving the sanitation of chlorinated wastewater treatment; Ilor and chlorine elements can be separated effectively and accurately, and the quality of Ilor-chlorinated wastewater treatment is improved. It should also be noted that this invention is a proposed separation method based on numerous studies. This invention proposes a method for the self-induced separation of chlorine and chloride, and its technological process and technical principle are briefly described below: The common ion effect is used, effectively exploiting a property of chloride to reduce the solubility of chloride. Using the difference in the solubility of fluoride and chloride in water, the concentration of chloride ions in chlorinated wastewater is increased to saturation by the external addition of a chloride salt. Since fluoride is difficult to dissolve in highly concentrated chloride solution, fluoride will precipitate in a crystal form. The liquid phase contains only chloride ions, and the solution is a saturated chlorine-containing solution. This saturated chlorine-containing solution continues to be crystallized to obtain extremely high-quality chloride crystals. In the actual operation, when 38761.07 chlorinated salt is added to precipitate the chloride, some of the chloride will grow on the chloride surface. Meanwhile, the precipitated Ilor and chlorine mixture crystals contain not only Iloride but also chloride. This invention exploits the common ion effect and effectively exploits a property of chloride to reduce the solubility of chloride. When chloride and chlorine mixture crystal and external chloride are added to a mixing and dissolving tank, the concentration of chloride ions continues to increase and the solubility of chloride ions decreases with the increase of the cycling index. After mixing, when the concentration of Iloride ions reaches saturation, Iloride crystals can be separated directly by solid-liquid separation; The remaining solution is recycled, thus separating the chloride and chloride and separately recovering the chloride and chloride crystal salts. It should be noted that, under the influence of the common ion effect of the elements chloride and chlorine, as shown in Figure 2, when the concentration of sodium chloride exceeds 240 g/L, the solubility of NaF becomes zero. In the first embodiment of this application, in step 3), a water-soluble Iloride salt is added to the mixed solution containing Iloride and chlorine, increasing the concentration of Iloride ions in the solution until supersaturation is reached, i.e. the included Iloride salt does not dissolve. In a preferred embodiment, the water-soluble Iloride salt obtained in this step may ultimately become the Iloride crystal obtained in step 3) to form a circulation. When the concentration of Iloride ions in the mixed solution containing fluorine and chlorine becomes supersaturated, additional Iloride crystals are not required. It should be understood that step 3) can actually be divided into two steps: first, adding a water-soluble salt of Iloride 38761.07 to increase the concentration of Iloride ions in the mixed solution containing Iloride and chlorine until the concentration of Iloride ions becomes supersaturated; and secondly, dissolving the above-obtained Ilor and chlorine mixed crystal salt to obtain a Iloride crystal and a high Ilor and high chlorine mixed solution by solid-liquid separation, since the Iloride salt is insoluble. In the first embodiment of this application, in step 1), the concentration of chloride ions in the chlorinated wastewater is improved by adding a water-soluble chloride salt to the chlorinated wastewater. The co-ion effect between fluoride and chloride ions is used, that is, the higher the concentration of chloride ions in the same solution, the lower the solubility of chloride ions. In other words, when the concentration of chloride ions in the solution increases, the Iloride ions will preferentially precipitate from the solution to obtain Ichloride crystals, and when the concentration of chloride ions in the solution continues to increase until the chloride ions become supersaturated, all the Iloride ions in the Ilor-chlorinated wastewater will precipitate in the form of crystals, thus A solution containing saturated chlorine will be obtained. The saturated chlorine-containing solution is subjected to direct crystallization to obtain a chloride crystalline salt. In the process of adding water-soluble chloride salt, when the chlorine salt in the added solution becomes insoluble or the concentration of the chloride ion is less than a certain value, it is concluded that the chlorine addition is completed. In a preferred embodiment, the chloride salt added in step 1) may be the chloride crystalline salt finally obtained in step 2). As the process progresses, only a portion of the chloride crystalline salt from step 2) needs to be incorporated. In the first embodiment of this application, since the Ilor and chlorine mixture crystal obtained in step 1) contains chloride ions during the circulation in step 3), the chloride ion concentration, Cci, in the high Ilor and high chlorine mixed solution will continue to increase. According to the common ion effect, the higher the chloride ion concentration 38761.07, the lower the solubility of Iloride ions, that is, the constantly increasing chloride ion concentration can promote the precipitation of Iloride ions in the form of crystals. However, when the concentration of chloride ions, Cci, is close to the saturation concentration, chloride ions can also precipitate in the form of crystals. Therefore, finally monitor the concentration of chloride ions, Cci, in the high chlorine and high chlorine mixed solution obtained in step 3), in step 1) to prevent the precipitation of chloride crystalline salts in the high chloride and high chlorine mixed solution in step 3). The chlorinated waste is passed into the water. At the same time, when the high-chlorine and high-chlorine mixed solution containing high concentrations of chloride ions is passed into the chloride-chlorinated wastewater, the process requirement for increasing the chloride ion concentration of the solution in step 1) can be further improved. In the first embodiment of this application, solids are precipitated in both step 1) and step 3), thus solid-liquid separation is involved in the entire embodiment. Solid-liquid separation methods in the embodiment provided in this application include, but are not limited to, one or more selected from centrifugal separation, gravity sedimentation, and filtration separation. The crystallization process method in step 2) includes one or more selected from, but not limited to, evaporative crystallization, refrigeration crystallization, and freeze-drying crystallization. The methods can be flexibly selected according to the requirements of the existing equipment production process. In the second embodiment of the present invention, the system for the self-induced separation of chlorine and chlorine includes a chlorine addition and salt precipitation apparatus, a mixing and dissolving and precipitation apparatus, and a solution crystallization apparatus. 38761.07 The above equipment is installed in the entire system sequentially according to the process requirements. The current system performs the process of adding chlorine to chloride-chlorinated wastewater through a chlorine addition and salt precipitation apparatus, in order to increase the concentration of chloride ions in the wastewater until it becomes supersaturated, to obtain a saturated chlorine-containing solution and a chlorine and chlorine mixture crystal. The saturated chlorine-containing solution is subjected to crystallization through the solution crystallization apparatus to obtain a chloride crystalline salt. The fluorine and chlorine mixture crystal is dissolved through a mixing and dissolving and precipitating apparatus to obtain a mixed solution containing fluorine and chlorine. Iloride is added to the mixed solution containing Iloride and chlorine to supersaturate the concentration of Iloride ions in the mixed solution containing fluoride and chlorine, so that Iloride in the crystal of Iloride and chlorine mixture cannot dissolve and separation is carried out to obtain an Iloride crystal. The technical solution provided by the present application can improve the efficiency of separating chloride crystal and chloride crystal salt from chloride-chlorinated wastewater. In the second embodiment of the present application, the chloride crystalline salt discharged from the solution crystallization apparatus is introduced into the chlorine addition and salt precipitation apparatus to increase the concentration of chloride ions in the wastewater until it becomes supersaturated, thereby reducing the use of extra additives. In the second embodiment of the present application, the Iloride crystalline salt discharged from the mixing and dissolving and precipitating apparatus is reconnected to the mixing and dissolving and precipitating apparatus to increase the concentration of Iloride ions in the mixed solution containing Ilor and chlorine, thus reducing the use of extra additives. 38761.07 It should also be noted that in current technology, conventional evaporation of chlorinated wastewater adopts single-stage evaporation. Without effective control, mixed crystalline salt of Ilor and chlorine can be obtained. Therefore, it can also be said that the present invention controls the conventional evaporation technology and the separation of chlorine and chlorine is achieved by cyclic crystallization with redissolution and concentration. Separation of fluorine and chlorine can be achieved with the simplest setting without using special equipment. Compared with the prior art, the present invention has the following beneficial effects. 1. The technical scheme provided by this application is able to separate chloride crystals and chloride crystal salts from chloride-chlorinated wastewater simply and quickly. 2. The technical solution provided by this application has simple process control, and the process can be quickly controlled by simply detecting the concentration of chlorine element and Ilor element separately to obtain Iloride crystal and chloride crystalline salt. 3. The technical solution provided in this application adopts traditional processing methods to treat wastewater by the established method, which can reduce the initial investment cost of chlorinated wastewater treatment plants. 4. In the technical solution provided by this application, the wastewater in the process is treated mainly with substances produced in the process in order to reduce the demand for additional additives and thus reduce the cost of consumables in the chlorinated wastewater treatment process. 38761.07 BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow chart of the method for the self-induced separation of chlorine and chlorine in the technical solution of the present invention; FIGURE 2 is a curve showing the change of F ion concentration in a saturated NaF solution with the added amount of NaCl; and FIG. 3 is a structural flow chart of the system for the self-induced separation of chlorine and chlorine in the technical solution of the present invention; Reference numbers in the attached figures are given below: 1 chlorine addition and salt precipitation apparatus, 2 mixing and dissolving and precipitating apparatus, 3 solution crystallization apparatus; L0 is the chlorinated-chlorinated waste water pipeline, L1 is the first high chlorinated circulation pipeline and L2 is the second high chlorinated circulation pipeline. The parts in the figures are numbered one by one, and the equivalents of these numbers are given below. 1. Chlorine adding and salt precipitation apparatus 2. Mixing and dissolving and precipitating apparatus 3. Solution crystallization apparatus water 38761.07 101. Add chlorine and precipitate a salt 102. Solid liquid separation 111. Fluorine-chlorine mixture crystallization 112. Mixing and dissolving 1 13. Solid-liquid separation 114. Fluoride crystallization 1 15. Sales 1 16. Fluoride 117. Highly mixed solution 121. Saturated chlorine-containing solution 122. Crystallization 123. Chloride crystal salt 124. Sales 125. Chloride DETAILED DESCRIPTION OF THE INVENTION According to a first embodiment of the present invention, a method for the self-induced separation of chlorine and chlorine is provided. A method for the self-induced separation of fluorine and chlorine involves the following steps: 1) obtaining a saturated chlorine-containing solution: subjecting the fluoro-chlorinated wastewater to chlorine addition to increase the concentration of chloride ions in the fluoride-chlorinated wastewater until the chloride ions become supersaturated. Thus, all the chloride ions and some of the chloride ions in the wastewater are crystallized to obtain a mixture crystal of chloride and chloride, and the liquid phase is a saturated chlorine-containing solution; 2) obtaining a chloride crystalline salt: subjecting the saturated chlorine-containing solution obtained in step 1) to a crystallization process to obtain a chloride crystalline salt; and 3) separating 38761.07 to obtain a Iloride crystal: Dissolving and repeatedly dissolving the Iloride and chlorine mixture crystal obtained in step 1) to obtain a mixed solution containing Iloride and chlorine, and adding Iloride externally to obtain a Iloride crystal. leaving for. In the present invention, by repeatedly dissolving Iloride and adding it externally, the concentration of Iloride ions in the mixed solution containing chlorine is increased until the Iloride ions become supersaturated, thereby crystallizing the Iloride ions to obtain an Iloride crystal. Preferably, in step 3), the concentration of Iloride ions in the mixed solution containing Iloride and chlorine is achieved by specifically adding a water-soluble Iloride salt to the mixed solution containing Iloride and chlorine until the Iloride ions become supersaturated, until the added Iloride salt is no longer dissolved. Preferably, the water-soluble Iloride salt is the Iloride crystal obtained in step 3. Preferably the water-soluble Iloride powder is commercially available Iloride. Preferably, in step l), increasing the concentration of chloride ions in the chlorinated wastewater until the chloride ions become supersaturated is specifically accomplished by: adding a water-soluble chloride salt into the chlorinated wastewater until the chlorine addition completion conditions are met and the chloride addition process is completed. addition, where the conditions for completing the chlorine addition are the insolubility of the added chloride crystal salt or the concentration of chloride ions in the chlorinated wastewater as CF, CF<0.1 g/L, preferably CF<0.05 g/L; and more preferably CF<0.01 g/L. 38761.07 Preferably the water-soluble chloride salt is the chloride crystalline salt obtained in step 2). Preferably the water-soluble chloride salt is commercially available chloride. Preferably, the method also includes the following steps: 4) After the chloride ions are crystallized to obtain a chloride crystal with a chlorine and chlorine mixed solution as the liquid phase in step 3), the chloride ions in the high chlorine and high chlorine mixed solution obtained in step 3) determining the concentration of chloride ions, Cci; and if introducing the high chlorine mixed solution into the chlorinated-chlorinated wastewater in step 1), otherwise introducing the high chlorinated and high chlorinated mixed solution into step 3) as a dissolving mother liquor. Preferably, in step 1) and step 3), one or more centrifugal separation, gravity sedimentation and filtration separation methods are used for solid-liquid separation. Preferably, the crystallization process in step 2) is one or more of evaporative crystallization, refrigeration crystallization, and freeze-drying crystallization. Preferably, chlorinated wastewater is a water-soluble chloride salt or wastewater containing a chloride salt, or a mixture of wastewater containing a water-soluble chloride salt and wastewater containing a water-soluble chloride salt. Preferably, it is one or more selected from high salinity wastewater, wastewater containing sodium chloride and sodium chloride, wastewater containing 38761.07 potassium chloride and potassium chloride, and wastewater containing ammonium chloride and ammonium chloride. Preferably, the concentration of chloride ions in the chlorinated wastewater is 0.05 g/L-15 g/L and the concentration of chloride ions is 0.01 g/L-150 g/L. According to the second embodiment of the present invention, a system for the self-induced separation of Ilor and chlorine is provided: Using the method of the first embodiment, the system for the self-induced separation of Ilor and chlorine includes a chlorine addition and salt precipitation apparatus (1), a mixing and dissolving and precipitation apparatus (2). ) and a solution crystallization apparatus (3), wherein a chlorinated wastewater pipeline (L0) is connected to a liquid inlet of the chlorine addition and salt precipitation apparatus (1); a feed inlet of the chlorine addition and salt precipitation apparatus (1) is connected to a chloride source; a liquid outlet of the chlorine addition and salt precipitation apparatus (1) is connected to a liquid inlet of the solution crystallization apparatus (3); a chloride crystalline salt is discharged from the solid outlet of the solution crystallization apparatus (3); a solid outlet of the chlorine addition and salt precipitation apparatus (1) is connected to a feed inlet of the mixing and dissolving and precipitation apparatus (2); a feed inlet of the mixing and dissolving and settling apparatus (2) is connected to a source of chloride; and a chloride crystalline salt is discharged from a solid outlet of the mixing and dissolving and precipitating apparatus (2). Preferably, the chloride source solution to be supplied to the feed inlet of the chloride addition and salt precipitation apparatus (1) is the chloride crystalline discharged from the crystallization apparatus (3). It is the Iloride crystalline salt discharged from the apparatus (2). Preferably, a liquid outlet of the mixing, dissolving and settling apparatus (2) is connected back to the feed inlet of the mixing, dissolving and settling apparatus (2) via a first high Ilor circulation pipeline (L1); or it is connected to the chlorine addition and salt precipitation apparatus (1) via a second high Ilor circulation pipeline (L2). Preferably, a chloride ion concentration sensor is arranged at the liquid outlet of the mixing and dissolving and settling apparatus (2). Examples A method for the self-induced separation of fluorine and chlorine includes the following steps: l) subjecting a chlorine-chlorinated wastewater to a chlorine addition process to increase the concentration of chloride ions in the chloride-chlorinated wastewater until the chloride ions become supersaturated, creating a saturated chlorine-containing solution. was obtained, so that all the chloride ions and some of the chloride ions in the wastewater were crystallized to obtain a mixture crystal of chloride and chlorine, and the liquid phase was a saturated chlorine-containing solution; 2) subjecting the saturated chlorine-containing solution obtained in step 1) to a crystallization process to obtain a chloride crystalline salt; 3) 38761.07 was separated by dissolving the mixed crystal with chlorine and chloride obtained in step 1) to obtain a mixed solution containing chloride and chloride, and then obtained a crystal of chloride by repeatedly dissolving and externally adding and separating chloride. . In Step 3), Example 1 was repeated except that the concentration of Iloride ions in the mixed solution containing Ilor and chlorine was achieved by specifically adding a water-soluble Iloride salt to the mixed solution containing Ilor and chlorine until the Iloride ions became supersaturated, until the added Iloride salt was no longer dissolved. The water-soluble Iloride salt is the Iloride crystal obtained in step 3. In step l), increasing the concentration of chloride ions in the chlorinated wastewater until the chloride ions become supersaturated is specifically achieved by adding a water-soluble chloride salt to the chlorinated wastewater until the chlorine addition completion conditions are met and the chlorine addition process is completed. 2 was repeated, where the conditions for completing the chlorine addition are the insolubility of the added chloride crystal salt or the concentration of chloride ions in the chlorinated wastewater as CF, CF<0.1 g/L, preferably CF<0.05 g/L; and more preferably CF<0.01 g/L. The water-soluble chloride salt is the chloride crystalline salt obtained in step 2). Example 3 was repeated except that the method also included water steps: 4) After the lauride ions were crystallized to obtain a laureate crystal with a mixed solution of laureates and chlorides as the liquid phase in step 3), the high laureates and chlorides obtained in step 3) The concentration of chloride ions in the chlorinated mixed solution, Cci, was determined as 38761.07; and if Cci is 80 g/L, the high chlorinated and high chlorinated mixed solution was introduced into the chlorinated-chlorinated wastewater in step 1), otherwise, the high chlorinated and high chlorinated mixed solution was introduced into step 3) as a dissolving mother liquor. has been included. Example 4 was repeated except that in step 1) and step 3) the solid-liquid separation was performed using filtration separation. In step 2), the crystallization process was carried out by evaporative crystallization. Example 5 was repeated except that the fluorochlorinated wastewater was wastewater containing a water-soluble chloride salt or chloride salt. Example 5 was repeated except that the fluorochlorinated wastewater was a mixture of wastewater containing a water-soluble chloride salt and wastewater containing a water-soluble chloride salt. Example 5 was repeated except that the fluorinated-chlorinated wastewater was a high salinity wastewater that was a mixture of sodium chloride and wastewater containing sodium chloride, wastewater containing potassium chloride and potassium chloride, and wastewater containing ammonium chloride and ammonium chloride. 38761.07 Example 5 was repeated except that the concentration of chloride ions in fluoride-chlorinated wastewater was 0.05 g/L-15 g/L. A system for the self-induced separation of Ilor and chlorine using the method of the first embodiment comprised a chlorine addition and salt precipitation apparatus (1), a mixing and dissolving and precipitating apparatus (2) and a solution crystallization apparatus (3), wherein a Iloru- the chlorinated wastewater pipeline (L0) is connected to a liquid inlet of the chlorine addition and salt precipitation apparatus (1); a feed inlet of the chlorine addition and salt precipitation apparatus (1) is connected to a chloride source; a liquid outlet of the chlorine addition and salt precipitation apparatus (1) is connected to a liquid inlet of the solution crystallization apparatus (3); a chloride crystalline salt is discharged from the solid outlet of the solution crystallization apparatus (3); a solid outlet of the chlorine addition and salt precipitation apparatus (1) is connected to a feed inlet of the mixing and dissolving and precipitation apparatus (2); a feed inlet of the mixing and dissolving and settling apparatus (2) is connected to a source of chloride; and a chloride crystalline salt was discharged from a solid outlet of the mixing and dissolving and precipitating apparatus (2). Example 8 was repeated, except that the chloride source to be supplied to the feed inlet of the chlorine addition and salt precipitation apparatus (1) was the chloride crystalline salt discharged from the solution crystallization apparatus (3). Example 9 was repeated except that the source of Ilauride 38761.07 to be supplied to the feed inlet of the mixing and dissolving and settling apparatus (2) was the Ilauride crystalline salt discharged from the mixing and dissolving and settling apparatus (2). Example II Connecting a liquid outlet of the mixing and dissolving and settling apparatus (2) back to the feed inlet of the mixing and dissolving and settling apparatus (2) via a first high Ilor circulation pipeline (L1); Example 10 is repeated except that it is connected to the chlorine addition and salt precipitation apparatus (1) via a second high fluorine circulation pipeline (L2). Example II is repeated except that a chloride ion concentration sensor is arranged at the liquid outlet of the mixing and dissolving and settling apparatus (2). The experiment was carried out according to the method for self-induced separation of fluorine and chlorine realized by the present application. Previously obtained chlorinated wastewater was used. After determining the concentration of chloride ions and chloride ions in fluorinated-chlorinated wastewater, experiments were started. In step 3), the determined value of the high chlorine and high chlorine mixed solution was obtained after the second circulation. The test results are shown below.TR TR TR