KR100699458B1 - Disinfectant filter combined with silver ion and iodine resin - Google Patents

Abstract

The present invention relates to a sterilizing filter using a sterilizing resin or a sterilizing polymer which can significantly increase sterilizing power and reduce disinfection byproducts by using silver ions or silver nanoparticles and an iodine sterilizing resin mixed or connected in parallel. Sterile filter of the present invention are known to exhibit germicidal ion or represents a synergistic effect when used by mixing the nanoparticles with an iodine resin, which after sterilization by-products are ions (Ag ⁺⁾ and an iodine ion (I ^-) is AgI It is a sterilization filter manufactured to be applied to drinking water by supplementing two important matters to increase sterilization power of existing sterilization filter and to reduce disinfection by-products by producing less by-products.

Disinfection Equipment, Sterilization, Silver, Iodine, Synergy

Description

Disinfectant filter combined with silver ion and iodine resin

1 is a cross-sectional view showing an example of a sterilizing filter in which a iodine-related resin and a silver-carrier compound containing iodine or iodine anion of the present invention are mixed.

2 is a cross-sectional view showing an example of a sterilizing filter in which the iodine-related resin and silver-carrier compound containing iodine or iodine anion of the present invention are provided in parallel.

Figure 3 is a flow chart showing an example of a sterile filter is provided with iodine-related resin and silver-carrier compound containing the iodine or iodine anion of the present invention.

Description of the main parts of the drawing

10-water source 20-preliminary filtration means

30-Iodine-Silver Carrier Filter 40-Disinfectant Water

50-sterilization filter unit

1-Silver Ion Carrier 2-Iodine Compound Resin

3-Case 4-Filter Cloth

5-Cap 6-Flow Control

7-water line 8-separator

The present invention relates to the manufacture of a filter having a strong sterilizing power by using a mixture of silver ions or silver nanoparticles and iodine disinfection resin or connected in parallel, the sterilization filter according to the present invention instant sterilization and sterilization of various bacteria and by-products It is manufactured to significantly reduce the.

Conventionally, silver nanoparticles were used as a silver-sterilizing filter by adsorbing or adhering to a specific adsorbent, but the use value was low because the sterilizing power was very weak. When a silver sterilization filter manufactured by adsorbing or adhering silver nanoparticles to a specific adsorbent and an iodine related sterilization filter manufactured using iodine anion resin or iodine resin are used as fillers of a sterilization filter, a certain amount of silver or iodine Since the compound may be eluted, silver or iodine compounds are contained in the sterilized water, so its use is limited to applications such as drinking water disinfection.

The present invention relates to an instant sterilization filter having a function of instantaneously disinfecting a part or an object contaminated with bacteria, which is convenient to use without electrical auxiliary facilities, and can completely sterilize various germs by instant contact. In addition, the long life is to provide a sterilizing filter that can be used in the long term.

The present invention finds that when a small amount of iodine is continuously contacted with silver ions having weak bactericidal power, the present invention has a very high bactericidal power. An iodine-related resin prepared to gradually elute iodine to a constant concentration over a long period of time The present invention provides a sterilization filter prepared by mixing or continuously providing a filter and a filter containing silver ions or silver nanoparticles inside a sterilization filter.

In addition, by examining the sterilization power of the filter containing silver ions or silver nanoparticles according to the elution amount of iodine to provide an optimum instant sterilization filter.

The present invention is to provide a sterilization filter that can be used for disinfection of drinking water, medical equipment for various disinfections, preparing disinfectant water such as vegetables, fruits and dishwashers and bidets, sterilization plates of washing machines, and sterilization filters of air conditioners.

The present invention relates to a sterilizing filter having a strong sterilizing power, the sterilizing power of a conventional sterilization filter using silver ions is very weak, but when the contact with a small amount of iodine is activated silver ions have a very strong sterilizing power I use it.

The silver ions are adsorbed or bound to a suitable carrier selected from cation exchange resins, zeolites or activated carbons, and then eluted through the iodine anionic resin or iodine resin.

The present invention is an ion or is a silver store monovalent silver salt or silver nano-particles is adsorbed or bonded or the like activated carbon or a polymer with a filter containing the nanoparticles (hereinafter, silver-carrier) using and, I ₃ ^-, I ₅ ^- To prepare a iodine anion resin or iodine resin using an anion resin, a salt of I ₇ ^- or a compound of I ₂ , or an iodine sterilization filter prepared by combining iodine compounds with activated carbon, ultra high molecular polyethylene, and the like The anionic resin or iodine resin and the silver-carrier compound may have a granule shape with particles of 0.5 to 5 mm in size.

The sterilization filter of the present invention is filled with a iodine anionic resin or iodine resin at the upper end of the case, and the silver-carrying compound is filled at the lower end of the case, and both ends are sealed with a filter cloth and then the cap is provided with a cap. When the water is passed through the iodine resin or the iodine resin through the finishing treatment, a small amount of iodine is continuously eluted, and silver ions or silver of the sterilization filter containing silver ions or silver nanoparticles in which the eluted iodine is continuously connected. promote the activation of the nano-particles shows a high disinfecting effect, after disinfecting silver ion (Ag ⁺⁾ and an iodine ion (I ^-), because the removal is precipitated AgI is possible to reduce the disinfection by-products.

Hereinafter, the present invention will be described in more detail.

The method for preparing the silver-iodine sterilization filter of the present invention is as follows.

Iodine and iodide are mixed to dissolve iodine and iodide in high concentration in a minimum amount of water, and then bonded to an anion exchange resin to prepare a iodine anion resin. The iodine compound in the ionic form _{^{(I 3 -, I 5 -}} , I 7 -) is a mixture of iodine, 1 to 4 mol and iodine flame 1 mol, preferably a mixture of iodine 2-3 mol periodate flame 1 mole It is prepared by dissolving in a minimum amount of water. The iodine compound prepared above was immersed in an anion exchange resin (Amberite series, Dowex series, Diaion series) (AS) for about 1 day to obtain a resin containing iodine anion containing 5 to 80% by weight of iodine anion. It is prepared using 5 to 80% by weight of the resin containing the prepared iodide anion. Silver-carrier compounds containing 5 to 60% by weight of silver ions are prepared by adsorbing or binding silver ions to activated carbon or a polymer according to a conventional method, and preparing the silver-carrier compound to 95 to 20% by weight. use. The prepared iodine anion resin was filled at the top through which water passes through the membrane inside the case, and the silver-carrier compound was filled at the bottom to contain a filter using iodine-related resin and silver ions or silver nanoparticles. A silver-iodine sterilization filter was prepared having the filter continuously inside the sterilization filter.

The manufactured iodine sterilization filter has a iodine anion resin filled in the upper part of the case and a silver-carrying compound in the lower part of the case, with the boundary of the separator inside the case, but for use of the silver iodine sterilizing filter. Therefore, the iodide ion resin and the silver-carrier compound are filled differently. When disinfecting drinking water, the weight of iodine resin should be 1-20%, so that iodine compounds or silver by-products such as silver should be contained in the disinfected by-product, and when used for other purposes, the filling of iodine resin Use up to 80% by weight.

Another method for producing the sterilizing filter of the present invention is to dissolve iodine in a minimum amount of alcohol such as ethanol or methanol to activate activated carbon (S) (powder activated carbon or granular activated carbon with iodine adsorption capacity of 1000 or more) or anion exchange resin (AS) (Amberite series, Dowex series, Diaion series) to prepare a resin or activated carbon containing iodine ion containing 5 to 80% by weight of iodine ion, and 5 to 80 weight of resin or activated carbon containing iodine ion prepared above Use in%. Silver-carrier compounds containing 5 to 60% by weight of silver ions are prepared by adsorbing or binding silver ions to activated carbon or a polymer according to a conventional method, and preparing the silver-carrier compound to 95 to 20% by weight. use. After filling the iodine resin or activated carbon and the silver-carrying compound in the case as in the filling method of the sterilization filter, the both ends are sealed with a filter cloth and then finished with a cap equipped with a tube.

Silver-iodine sterilization filter prepared by the above manufacturing method has a very strong sterilizing power by activating the silver by iodine, and the disinfection by-products such as iodine or silver are removed and precipitated with AgI, which has high utility value.

Hereinafter, the preparation method of each sterilizing filter used for this invention is demonstrated through the manufacture example of this invention.

Preparation Example 1 Preparation of Diiodine Anion Resin

0.9 kg of iodine (I ₂ ) and 0.6 kg of potassium iodide (KI) were mixed with a iodide flame (in a 1: 1 molar ratio) to completely dissolve in 300 mL of water to prepare an iodine anion compound. In the prepared iodine solution, about 1.5 kg of anion exchange resin (IRA-402 of Amberber) was added and immersed for 24 hours to prepare a iodine anion resin.

Production Example 2 Preparation of Iodine Resin

Iodine (300g) was dissolved in ethanol (1,000ml) to activate activated carbon (S) (iodine adsorption force 1000

Iodine resin is prepared by adsorbing on the above powder activated carbon or granular activated carbon) or anion exchange resin (AS) (IRA-402 of Amberberite, 500 g).

Preparation Example 3 Preparation of Silver-Cation Resin

Silver nitrate (AgNO ₃ ) 150 meq (25.48g) is dissolved in 200 mL ultrapure water and prepared by ion exchange in cation exchange resin (Amberite IR-124, 20-50 mesh, sodium form, 300g) for 24 hours.

Preparation Example 4 Preparation of Silver-Zeolite

Silver nitrate (AgNO ₃ ) is prepared by dissolving 150 meq (25.48 g) in 200 mL of ultrapure water and ion-exchanging with zeolite (silver ion exchange A-type zeolite, 300 g) for 24 hours.

Preparation Example 5 Preparation of Silver-Activated Carbon

Silver nitrate (AgNO ₃ ) 150 meq (25.48g) was dissolved in 200 mL ultrapure water and then prepared by ion exchange with activated carbon (powder activated carbon, iodine 1300, 100g) for 24 hours.

Hereinafter, the present invention will be described with reference to examples for specific description of the present invention, but the present invention is not limited to the following examples.

Example 1

By using the iodine-related sterilizing filter manufactured using the iodine anion resin or the iodine resin prepared in Preparation Example 1 and Preparation Example 2 and the silver-carrier compound prepared from Preparation Example 3, Preparation Example 4 or Preparation Example 5 The sterilization power was investigated using a manufactured silver related sterilization filter.

As a comparative example, the bactericidal power of only 10 g of silver-carrier compound in water (①) and only 10 g of iodine anion resin in water (②) was investigated, and the composition of the silver-iodine sterilization filter according to the present invention. The sterilizing power of 5 g of silver-carrier compound and 5 g of iodine anion resin was mixed and immersed in water (③).

As shown in Table 1 below, 500 ml of the solution contaminated with the concentration of bacteria was immersed by mixing and immersing the silver-carrier compound, the iodine anion resin or the silver-carrier compound and the iodine anion resin for 5 minutes, 30 minutes and 1 hour. The sterilizing power over time is shown in Table 1 below.

TABLE 1

As shown in Table 1 above, as shown in Table 1, when only 10 g of silver-carrier compound was immersed in water (①), the sterilizing power was 20-40% after 60 minutes, but only 10 g of iodine anion resin was used. When immersed in water (②), 50-60% bactericidal power after 5 minutes and 70-80% bactericidal power after 60 minutes, but 5g silver-carrier compound which is a composition of the silver-iodine sterilization filter of the present invention When 5g of iodine anion resin was mixed and immersed in water (③), most of the bacteria were sterilized within 1 hour. The total weight of the sterilizing resin used in the three experiments was the same as 10g. As can be seen in Table 1, the sterilization power is rapidly increased when the sterilization resin is mixed and used (③), which is clearly a synergistic effect, because the silver ions are activated by iodine and the activated silver ions are further It is judged to exhibit high sterilizing power. Through the experiment it can be seen that the sterilizing power is increased due to the synergistic effect between the iodine resin and silver ions of Preparation Examples 1 to 6.

Example 2 Sterilization and Disinfection By-Product Comparison

5cm filled with cation resin adsorbed silver ions to glass column (25 * 200mm) (1) and 1cm filled with iodine anion resin (②) and 5cm filled silver ion-cationic resin at the bottom Afterwards, the disinfection of silver ions and iodine compounds was compared with the sterilization power in the case of 1 cm filled with iodine anion resin (③). Microbe preparation is then made to 500 mL with table concentrations below, was passed through at a flow rate of 50 mL / min on each column receives the effluent concentration of the silver concentration and the iodine compound of the microorganism ^{_{(I 2 + I - + IO}} 3 -) The concentration of was measured. The results are shown in Table 2.

TABLE 2

As shown in Table 2, in the case of a glass column filled with only 5 cm of cation resin adsorbed with silver ions in the sterilization test (1), the sterilization power was 10-20% and the sterilization power of the iodine resin was excellent. In case of glass column filled with only 1cm of iodine anion resin (②), it showed 80-90% sterilization power.In case of filling iodine anion resin at the top and silver ion-cationic resin at the bottom (③) It can be seen that the bacteria are sterilized. As shown in Example 1, the eluted iodine activates silver ions, and thus, the bactericidal power is improved, and a resin capable of eluting iodine is at the top, and a resin or carrier having silver ions or silver nanoparticles is at the bottom. Effective when in

The elution amount of silver ion and iodine compound was investigated. Large amounts of iodine in drinking water can cause thyroid hypertrophy and silver is toxic, so the dissolution of iodine or silver after sterilization should be minimized. USEPA regulates the concentration of silver below 50 ng / mL in drinking water. In Table 2, when the glass column packed with only 5 cm of cation resin adsorbed silver ions (1), the concentration of silver in the eluate was 85 ng / mL. However, when using a glass column filled with 5 cm of silver ion-cationic resin at the bottom and 1 cm filled with iodine anion resin at the top (③), it was observed that the concentration of silver was reduced to 2 ng / mL. By-products, silver ions and iodine ions combine to form AgI and are deposited and removed in the resin. When using a glass column filled with only 1 iodine anion resin in the elution amount of iodine compound (②), the concentration of iodine was 150 ng / mL, but the silver ionic-cationic resin was charged 5 cm at the bottom, followed by iodine at the top. When using a glass column filled with an anion resin (1 cm) (③), it was observed to decrease to 5 ng / mL, which is also an Ag disinfection by-product, which is eluted as described above. This is because it is deposited in the ground and removed.

The silver-iodine sterilization filter manufactured by the manufacturing method of the present invention can provide a high disinfection power as a synergistic effect of silver and iodine as well as give a low disinfection byproduct after disinfection.

In addition, it is convenient to use without long electrical facilities, long life can be used for a long time, this device can be used in places where disinfection of drinking water, various medical devices and appliances.

Claims (7)

A sterilizing filter comprising 5 to 80% by weight of a resin or iodine containing iodine anion and 95 to 20% by weight of a silver-carrier compound containing silver ions. The method of claim 1, A resin or activated carbon containing iodine anion is a sterilizing filter, characterized in that 5 to 80% by weight of iodine or iodine anion. The method of claim 1, A silver-carrying compound containing silver ions is a sterilizing filter characterized in that 5 to 60% by weight of silver ions. The method of claim 1, A silver-carrier compound is a sterilizing filter characterized in that it is selected from silver ion-cationic exchange resin, silver ion-zeolite, silver ion-activated carbon, etc. The method of claim 2 or 3, A sterilizing filter characterized in that a resin containing iodine anion or activated carbon and a silver-carrying compound containing silver ions are provided as granules and mixed with each other. The method of claim 5, A sterilizing filter characterized by granule-shaped iodide anion resin and silver-carrier compound of 0.5 to 5 mm particles. delete

Images