TR2022013897T2 - COATING MATERIAL AND COATING METHOD - Google Patents

Abstract

A coating material and a coating method are provided that can ensure that the antibacterial effect and the antiviral effect of a superficial layer of a coating target remain compatible with each other over a long period of time. The coating material comprises a coating material in which inorganic polysilazane and an alkyl silicate condensate are dissolved in an inert solvent at a total concentration of 50 to 80% by mass as base material (10A); It contains an inorganic antibacterial agent added to the base material (10A) at a rate of 0.1% to 5% by mass, and an inorganic antiviral agent added to the base material (10A) at a rate of 0.1% to 20% by mass.

Description

DESCRIPTION COATING MATERIAL AND COATING METHOD TECHNICAL FIELD The present invention relates to a coating material and a coating method to be used in the reconstruction of a superficial layer of an article or similar object that is the coating target. TECHNIQUE THAT CREATES THE INFRASTRUCTURE In the relevant technique, various articles or similar objects containing materials such as resin material, metal material, wood and rubber material are used as coating targets, a coating film is created by applying or spraying a coating material on the surface of the article or similar object, thus covering the superficial layer of the coating target. its antibacterial properties are improved and the coating objective is improved hygienically (see, for example, Cited Patent Document 1). In addition, a coating film is formed on the surface of the article or similar object, thus improving the antiviral properties of the superficial layer of the coating target. CITATION LIST Patent Literature SUMMARY OF THE INVENTION Technical Problem On the other hand, in the Cited Patent Document 1, since the coating material sprayed on the surface of the article enters the small concave and convex structures on the surface of the article in question and is applied in contact with the surface to which it is temporarily fixed, the coating material gradually peels off over time and loses its antibacterial effect. It is not possible to preserve it for a long time. Furthermore, although it is possible to obtain a certain antibacterial effect with a coating material as in the Cited Patent Document 1, it is not possible to expect a protective effect against viruses such as influenza virus. Also, the Patent Document Cited? When an antiviral coating material is used together with such an antibacterial coating material, there is a concern about the coating materials affecting each other, and therefore it is not possible to expect each of these effects to occur, and moreover, the surface of the coating target may also change. Especially with the recent emergence of the new coronavirus (covid-19) epidemic, it is desirable to use various items that will be in contact with people as targets and to reconstruct the superficial layer of these items in a way that not only the antibacterial effect but also the antiviral effect can be maintained for a long time. is done. The present invention has been realized by focusing on such problems and has an aim to provide a coating material and a coating method that can exert a compatible antibacterial effect and an antiviral effect in a superficial layer of a coating target for a long time. Solution to the problem In order to achieve the aim described above, the coating material according to the present invention is presented in the form of a coating material comprising: Inorganic polysilazane as base material and an alkyl silicate condensate dissolved in an inert (non-reactive) solvent at a total concentration of 50 to 80% by mass. a coating agent; An inorganic antiviral agent added to the base material at an amount of 0.1% to 0.1% to 20% by mass. Thanks to this feature, the glass coating film formed by inorganic polysilazane and alkyl silicate condensate is used as the main material, and the inorganic antibacterial substance and inorganic antiviral substance are fixed stably on the superficial layer of the coating film, and therefore, the antibacterial effect and antiviral effect on the coating target covered with the coating material can last for a long time. can remain compatible with each other throughout. In addition, the coating material can be distinguished by the fact that it contains an organic antibacterial/antiviral substance added to the base material at a rate of 0.1% to 10% by mass. Thanks to this feature, both the antibacterial effect and the antiviral effect of the coating target can be increased. A coating method according to the present invention comprises a coating agent in which inorganic polysilazane and an alkyl silicate condensate are dissolved in an inert solvent at a total concentration of 50% to 80% by mass as the base material, and an inorganic antibacterial agent is added to the base material at the rate of 0.1% to 5% by mass. It is a coating method comprising a coating step of coating a surface of a coating target with a coating material containing the substance and an inorganic antiviral agent added to the base material at a rate of 0.1% to 20% by mass. Thanks to this feature, a glass coating film containing inorganic polysilazane and alkyl silicate condensate is formed on the surface of the coating target, the glass coating film is used as the main material, and the inorganic antibacterial agent and inorganic antiviral substance are stably fixed on the superficial layer of the coating film, thus providing an antibacterial effect on the coating target. and antiviral effects can be achieved in harmony with each other. The coating step in the coating method can be a step of forming a coating film, which will be the main material containing SiO2 as the main component, in the form of a thin layer on the surface of the coating target and exposing the antibacterial substance and the antiviral substance to the superficial layer surface of the coating film. Thanks to this feature, the antibacterial agent and the antiviral agent are exposed to the superficial layer surface of the coating film, and therefore, the antibacterial agent and the antiviral agent directly act on various microbes or viruses, and the antibacterial effect and antiviral effect can be increased for a long time. Moreover, the coating film is formed in the form of a thin layer and therefore it becomes possible to provide the following capability regarding the behavior of the surface of the coating target. The coating step in the coating method is to coat the surface of the coating target to which moisture is bound with the coating material, to form a coating film on the surface of the coating target, which will be the main material containing SIO2 as the main component, through a chemical reaction that occurs between the components in the coating material and the moisture bound to the surface of the coating target, and It may be a step in which the antibacterial agent and the antiviral agent are exposed to a concave section on the surface of the superficial layer of the coating film formed as a result of the chemical reaction. Thanks to this feature, the antibacterial agent and antiviral agent are exposed to the concave section on the surface of the superficial layer of the coating film, formed by the discharge gas produced by the chemical reaction between the components in the coating material and the moisture on the surface of the coating target, and therefore, the antibacterial agent and the antiviral agent are exposed to the concave section on the surface of the superficial layer of the coating film. The substance acts directly on various microbes or viruses, and the antibacterial effect and antiviral effect can be enhanced for a long time. In addition, the particles of the antibacterial agent and the antiviral agent are arranged in the concave section on the superficial layer surface of the coating film, and therefore, the smoothness of the superficial layer surface can be increased. The coating method may also include a sterilization step of sterilizing the surface of the coating target prior to the coating step. Thanks to this feature, it becomes possible to create a coating film with good quality and high effect durability on the coating target surface cleaned through the sterilization step. The coating method may also include a pre-treatment step of binding moisture to the surface of the coating target prior to the coating step. Thanks to this feature, moisture is bound to the surface of the coating target and therefore, the chemical reaction between moisture and the components in the coating material is accelerated and the coating film can be formed instantly and firmly on the surface of the coating target. BRIEF DESCRIPTION OF THE DRAWINGS FIGS. 1A to 1C are sectional views showing, in chronological order, the mechanism for forming a coating film on an article within the framework of the Example. FIGURE 2 is an enlarged view of the section surrounded by the dotted line in FIGURE 1C. FIG. 3 is an enlarged view of the section surrounded by the dotted line in FIG. 1C, suitable for another application. FIG. 4 is a diagram showing an AFM measurement of a surface of a metal material coated with a coating film: FIG. 4A is a diagram showing the formation of a single layer of coating film; FIG. 4B is a diagram showing three layers of coating film. FIG. 5 is a table showing the results of an ATP wipe test. . DESCRIPTION OF EMBODIMENTS A coating material and methods of carrying out a coating method in accordance with the present invention will be explained below with reference to FIG. 1 to FIG. 5. Examples Coating Liquid As the coating material according to the present invention, the coating liquid (10) basically includes a base material (10A) and additives (1OB) added to the base material (10A). First of all, base material 10A contains at least inorganic polysilazane and an alkyl silicate condensate as raw materials, and in this example, the inorganic polysilazane and alkyl silicate condensate are diluted with an inert solvent. Inorganic polysilazane and alkyl silicate condensate are dissolved in this example in dibutyl ether as an inert solvent to a total concentration in the range of 50 to 80% by mass. More specifically, the inorganic polysilazane is present in the amount of 01 to 5% by mass, and the alkyl silicate condensate is present in the remaining proportion. More specifically, the inorganic polysilazane in this example is perhydropolysilazane, that is, containing a -(SiH2-NH)- unit, which includes a Si-H bond, a Si-N bond and an N-H bond, and is represented, for example, by the general formula (1) below. It is in the form of an inorganic polymer with a chain structure. It should be noted that Formula 1 Inorganic polysilazane is not limited to having a chain structure and can be a polymer with a cyclic structure or a polymer with a composite chain structure and cyclic structure. Alkyl silicate condensate, such as one or two or more selected from tetramethyl orthosilicate, tetraethyl orthosilicate, tetra-n-propyl orthosilicate, tetra-i-propyl orthosilicate, tetra-n-butyl orthosilicate, tetra-sec-butyl orthosilicate, methyl polysilicate, and ethyl polysilicate. It is in the form of excess condensate. The inert solvent is a solvent that is inert with respect to inorganic polysilazane and alkyl silicate condensates and is preferably selected from dibutyl ether, dimethyl ether, diethyl ether, dipropyl ether, turpentine oil, benzene, toluene and the like. Additives (1OB) are added to the base substance (10A) described above, within this framework, an inorganic antibacterial agent (21) is added at a rate of 0.01% to 10% by mass, an inorganic antiviral agent (22) is added at a rate of 0.01% to 40% by mass. and an organic antibacterial/antiviral agent (23) is added at a rate of 0.01 to 20% by mass. It should be noted that at least the inorganic antibacterial agent (21) and the inorganic antiviral agent (22) may be added, and the organic antibacterial/antiviral agent (23) may not be added. More specifically, the inorganic antibacterial substance (21) contains silver oxide-zinc calcium phosphate (Ag20-CauZnßAly(PO4)s). Furthermore, the inorganic antiviral agent 22 contains at least one molybdenum compound or a silver compound. Additionally, it contains the organic antibacterial/antiviral substance (23) diiodomethyl-p-tolylsulfone. Characteristics of the Coating Material In addition, the coating liquid (10) in this example is used, for example, as a predetermined amount of liquid sealed in a glass or resin container, and the liquid is applied to the surface of various items or similar objects that will be the coating target, a cloth material or a similar material (as shown in figures). (not shown) is applied by moistening it with the liquid in question to form a coating film. It should be noted that the use of the coating material is not limited to this and that, for example, a non-woven cloth or similar material previously impregnated with a coating liquid can be sealed in a bag and the bag can be opened at the time of use, or the coating liquid can be applied onto the surface of the coating target by spraying it in the form of a mist. Coating Method for the Coating Film: The coating liquid (10) is applied or sprayed on the surface (2) of the article (1) that will be the coating target, and thus, it forms single-layer or multi-layer coating films (15 and 35) by chemically reacting with moisture. It should be noted that the coating film (15) shown in FIGURE 2 is formed at the micro level. Moreover, the coating film (35) shown in FIG. 3 is formed in the form of a nano-thin layer, preferably with a film thickness in the range of 1 nm to 500 nm, and more preferably in the range of 5 nm to 200 nm. First, before the step of coating the coating films (15 and 35), a sterilization step of sterilizing the surface (2) of the article (1) is performed. In the sterilization step, a sterilization liquid in which hypochlorous acid, which has an antibacterial/antiviral effect in addition to its sterilization effect, is diluted is attached to the surface (2) of the article (1) by means of fog application or by a non-woven cloth or similar material impregnated with the sterilization liquid. Thanks to this type of sterilization, it is possible to create coating films (15 and 35) that have good quality and high effect durability, are easily applied to the surface (2) of the clean article (1), and are less likely to peel off. As a preliminary step, it should be noted that before the coating step and after the sterilization step described above, water (H2O), for example pure water, may bind to the surface (2) of the article (1) through non-woven cloth, fog or similar means. Thus, the chemical reaction between the moisture bound to the surface (2) of the article (1) and the components in the coating liquid (10) can be accelerated and the coating films (15 and 35) can be formed instantly and firmly on the surface (2) of the article (1). Coating Target Various articles containing materials such as resin material, metal material, wood, rubber material and leather can be applied as the coating target, or the coating target can be a fixed installation such as furniture and, for example, the surface of the processing unit of a mobile terminal or remote control, a row or Items that will be frequently contacted by many people, such as table tops or drawers, crockery, bags or wallets, door knobs or stair railings, electric train or bus grab straps, building materials and temporary materials, can be preferred as coating targets. Coating Film Formation Mechanism Now, the formation mechanism of the coating films (15 and 35) according to the present invention will be explained. As shown in Figure 11, in most cases, even if the amount of moisture is small, due to condensation of moisture or humidity in the air, a series of moisture grains (6, 6, ...) (6, 6, ...) (1) are attached to the surface (2) of the article (1) containing, for example, a metal material as the coating target. water droplet) is connected. In the case where the coating liquid (10) is applied or sprayed on the surface (2) of the article (1) in the form of a thin film, perhydropolysilazane, which is the inorganic polysilazane that structures the base substance (10A) in the coating liquid (10), reacts chemically with the moisture in the air (HZO) and thus, A coating layer with an inorganic structure is formed on the surface (2) of the article (1). It should be noted that a small amount of gas (NH3 and Hz) is additionally formed as a result of the chemical reaction explained above, but this gas volatilizes appropriately and mixes with the air without remaining on the surface (2) of the article (1). In other words, as shown in Figure 1, the coating liquid (10) enters into a chemical reaction with the moisture present in the air on the superficial layer surface (10a) that will be in contact with the air, and thus produces hydrogen or ammonia, which is the by-product of the coating films (15 and 35). A gas evaporates from the superficial layer and a coating layer (11) is formed on the surface side of the coating films (15 and 35). In addition, the coating liquid (10) applied to the surface (2) of the article (1) is formed on a back layer surface (10b) that will be in contact with the surface (2) of the article (1) in question, along with the moisture grains (6) bonded to the surface (2). 6, ...) (with water droplets) or with a hydroxyl group (-OH) present as the end group on the surface (2), and thus the gas, such as hydrogen or ammonia, rises in the coating layer to evaporate from the superficial layer and forms the coating films ( A coating layer (12) is formed on the back surface side (15 and 35). As explained above, first, coating layers (11 and 12) are formed on the superficial layer surface (10a) and the back layer surface (10b) of the coating liquid (10), respectively. Then, the coating layer (11) expands towards the back layer by the superficial layer, and the other coating layer (12) expands towards the superficial layer by the back layer, thus an intermediate coating layer is formed sequentially, and finally, it will be in contact with the outside air. Coating films (15 and ) are formed on a superficial layer surface (14a) and on a back layer surface (14b) that will be in contact with the surface (2) of the article (1). As shown in FIG. 1C, unless a special superficial layer treatment, such as a mirror-like finishing, is performed on the surface (2) of the article (1) before the formation of the coating films (15 and 35), a small defect or similar defect occurring during the production phase or similar As a result of a structure, a series of small concave-disvex sections (3) are formed at the micro level. When the coating liquid (10) is applied to the surface (2) of the article (1) and enters into the concave-convex section (3), it cures as explained above, and therefore, when it enters into the concave-convex section (3), the cured coating material forms a fixing section ( 17) and as a result, the coating films (15 and 35) are attached to the surface (2) of the article (1) more firmly and tightly. Additionally, as shown in FIG. 2 and Site, in the superficial layer and inner part of the coating films (15 and 35), the additives (1OB) contained in the coating liquid (10), namely inorganic antibacterial substance (21), inorganic antiviral substance (22) and organic antibacterial The antiviral agent (23) is mixed at the micro level in the form of a series of small particles, some of which are exposed to the superficial layer surface (14a) as described below. The coating film (15) shown in FIGURE 2 is formed at the micro level. Moreover, in another embodiment, the coating film (35) shown in FIG. 3 is formed at the nano level, which is thinner than that of the coating film (15) explained above. Therefore, even in the case of a glass coating film, the glass coating film is highly flexible, and this flexibility is also combined with the fixing effect of the fixing section 17 described above, and as a result, the surface 2 of the coating target is covered with cloth or similar material. It is possible to maintain the coating properties of the coating film (35) after the deformation of the surface (2), without peeling off the coating film (35), even if it causes deformation of the material. In case the surface (2) of the article (1) is a smooth surface with almost no space for the concave-convex sections (3) explained above, the article (1) can be removed by using a rasp or a similar tool as a coating pre-treatment for the coating film (15). It should be noted that as a result of carrying out a roughening process on the surface (2), concave-convex sections (3) can be actively formed on the surface (2) of the article (1), thus a fixing effect regarding the coating film (15) can be achieved. By performing such a roughening process, it is preferred to create concave-convex sections (3) with an arithmetic average roughness in the range of approximately 1 to 500 um on the surface (2) of the article (1) and thus to increase the fixing effect of the coating film (15). . After the roughening process, a cleaning process is carried out in which, for example, the metal dust produced by the rasp on the surface (2) of the article (1) is removed by blowing using an air injection tool such as an air gun. In addition, after the cleaning process, moisture condensation or a similar situation occurs on the surface (2) of the article (1) in a predetermined period of time, and the naturally produced moisture binds to the surface. Moreover, in this case, after the surface (2) of the article (1) is subjected to the roughening process and cleaning process, as a pre-treatment step before the coating step, the surface (2) of the article (1), on which concave-convex sections (3) are created by roughening, is applied to the surface (2), for example. Moisture can be actively bound by means of a moisture application tool such as fog, and then the coating film (15) can be applied, thus creating a gap between the moisture bound to the surface (2) of the article (1) and the coating liquid (10) that will contact the surface (2) of the article (1). The chemical reaction can be accelerated. It should be noted that moisture can be attached to the surface (2) of the article (1) through moisture application means and especially without performing the roughening process. The Shape of the Coating Layer of the Coating Film As shown in FIGURE 2, the concave-convex sections (16) are formed on the superficial layer surface (14a) of the coating film (15) at the nano level and the coating film applied to the surface (2) of the article (1). It is formed in the traces of volatilized gas bubbles belonging to the by-product gas located on the (15) surface. More specifically, it is assumed that a large number of bubbles of hydrogen, ammonia or the like are formed as a result of the chemical reaction described above, and when these air bubbles are discharged into the air from the smooth superficial layer surface (14a) of the coating film (15), they enter the coating film (15) in contact with the air bubbles. The effect of the surface tension occurring on the smooth superficial layer surface (14a) of the surface layer (14a) comes together with the effect of the initial curing time of the superficial layer surface (14a) as a result of the chemical reaction, and therefore, the surface containing concave sections (16b) and convex sections (16a) at the nano level is formed. concave-convex sections (16) are formed on the smooth surface. It should be noted that in FIG. 1 and FIG. 2, the concave-convex dimension of the concave-convex section (16) is shown deformed according to the actual size, and the concave-convex section (16) is not included in FIG. In addition, the concave-convex section (16) formed on the surface of the coating films (15 and 35) has a smaller depth and width compared to the concavities and convexities of the concave-convex section (3) formed initially before the surface (2) of the article (1) is coated. Since it has a height dimension, by applying the coating films (15 and 35) to the surface (2) of the article (1), the surface is created smoother after coating compared to before coating. Of course, the gas, which is the by-product explained above, is formed homogeneously on the surface of the coating film (15) and therefore the number of pits per unit area of the coating film (15) is equal to the number of pits (16) without any variation in the depth of the concave section and the height of the convex section. It should be noted that it was created in a certain way. Furthermore, regarding the coating films (15 and 35) to be applied to the surface (2) of the article (1), in the case of a single-layer coating, as shown in FIG. 4Al, the pits (16) formed on the coating films (15 and 35) are shown in FIG. 4B. Compared to the pits (26) formed on the coating films (15 and 35) in the case of a multi-layer coating such as, the pits (26) in the case of a multi-layer coating have smaller depth and height dimensions in concavities and convexities. can be seen. It is assumed that the reason for this is that the coating film is applied more than once, thus the concavity and convexity of the pits 16 when the single-layer coating is present are flattened and smoother pits 26 are formed. In addition, part of the surfaces of the additives (B), namely the inorganic antibacterial substance (21), inorganic antiviral substance (22) and organic antibacterial/antiviral substance (23), which are mixed in the form of small particles in the coating films (15 and 35), are attached to the superficial layer surface (14a). ) is fixed in an externally open state. More specifically, as explained above, perhydropolysilazane, which structures the base substance (10A) of the coating liquid (10), additionally produces gas (NH3 and Hz) as a result of the chemical reaction with moisture (H20), and this gas produces small amounts of additives (B). It rises around the gas in the coating liquid (10) together with the particles. Therefore, as shown in FIG. 21, some of the additives (B) in the coating liquid (10) are located near the superficial layer surface (14a) of the coating film (15), and especially in the concave-shaped layers formed on the superficial layer surface (14a) by the volatilized gas. It is collected in the convex section (16). A portion of the small particles of the additives (B) are arranged on the superficial layer surface (14a) to complete the concave shape of the concave section (16b). Therefore, inorganic antibacterial substance (21), inorganic antiviral substance (22) and organic antibacterial/antiviral substance (23) directly affect various microbes or viruses, and the antibacterial effect and antiviral effect can be increased for a long time. In addition, additives (B) are placed on a part of the concave section (16b) and the smoothness of the superficial layer surface (14a) can be increased. Moreover, another part of the small particles of the additives (B) is arranged on the superficial layer surface (14a) to be placed in the inner part of the convex section (16a). Thus, in accordance with the use of the article (1) after coating, in the case where a part of the convex section (16a) with a protruding shape rubs against the superficial layer surface (14a) of the coating film (15), the additives (B) placed in the convex section (16a) are applied to the surface. becomes clear and therefore the antibacterial/antiviral effect can be maintained for a long time. Moreover, in the coating films (15 and 35) formed on the surface (2) of the article (1) by applying the coating liquid (10) in accordance with the present invention, the base contains an inorganic component and the additives antibacterial agent (21) and antiviral agent (22). They are also inorganic components and therefore, it is possible to maintain the coating film condition for a long time without leakage/gasification and degradation into the base material or outward. Moreover, the coating film (35), shown in FIG. as another embodiment, is formed at the nano level, which is smaller than that of the coating film (15) explained above, and more specifically, it has a film thickness in the range of approximately 1 to 500 nm. Against this; The inorganic antibacterial agent 21 has a particle diameter of about 0.8 to 1 µm, the inorganic antiviral agent 22 has a particle diameter of about 3 µm, and the organic antibacterial/antiviral agent 23 has a particle diameter of about 1 µm, of which all of them are larger than the film thickness of the coating film (35). Therefore, the upper parts of these particles are open to the superficial layer surface (34a) of the coating film (35). Therefore, inorganic antibacterial substance (21), inorganic antiviral substance (22) and organic antibacterial/antiviral substance (23) directly affect various microbes or viruses, and the antibacterial effect and antiviral effect can be increased for a long time. Moreover, the coating film (35) is formed in the form of a thin layer and thus, it is possible to provide the following capability in terms of behavior even when the surface (2) of the article (1) is flexible. In addition, since the base substance (A) is cured when a part of the particles belonging to the additives (B) are placed in the concave-convex section (3) formed on the surface (2) during the application of the coating liquid (10), it has an antibacterial effect and antiviral effect without peeling off. The effect can be maintained for a long time. Method for Evaluation of Antibacterial/Antiviral Effect As an evaluation method for the antibacterial/antiviral effect of the coating film, an adenosine triphosphoric acid (ATP) wipe examination on the surface (2) coated with coating films (15 and 35) was carried out stepwise and a test based on numerical ATP values was carried out. evaluation has been made. Here, ATP is a chemical substance present as the energy source of all living beings on earth, and it is possible to check the presence of ATP as evidence of the presence of bacteria/viruses themselves or traces of bacteria/viruses. In other words, when the numerical value in the ATP deletion examination is large, it is evaluated that the degree of contamination of the surface is high (the risk of infection is high), and when the numerical value in the ATP deletion examination is small, it is evaluated that the degree of contamination of the surface is low (the risk of infection is low). Now, ATP deletion review will be explained. In the ATP erasure examination, a glass sample (A) in which the surface was coated with the coating material according to the present invention, samples for comparative purposes (B to E) in which the surfaces were coated with the different types of coating material described below, and a sample not coated with any coating material (not indicated with any letter markings) ) are exposed to the normal temperature environment in the same experimental laboratory, ATP deletion is performed on the surface of each sample every day (every 24 hours) and a comparison is made for ATP detection numbers. It should be noted that a large number of people enter and exit the experimental laboratory, and therefore, the experimental laboratory is an environment where bacteria or viruses can invade. In the ATP wiping process performed on the surface, the surface of the sample is rubbed with the tip of a detection wire rod in the form of a cotton swab in a certain condition and the tip is placed in the ATP detector (not shown in the figures) used specifically for this purpose and thus the ATPl attached to the tip is removed from the sample (B) in the coating liquid according to the present invention. (10) is coated with a coating material containing only the base material (10A) without the presence of the additives (10B). The sample (C) is coated with an inorganic glass coating material intended for sporting goods or similar objects. Additionally, the sample (D) is coated with an inorganic glass coating material for a mobile terminal or similar object. Additionally, the sample (E) is coated with an inorganic ceramic coating material. Evaluation for Antibacterial/Antiviral Effect The results of the ATP deletion assay are shown in FIG. In the sample (A) coated with the coating material in accordance with the present invention, no gradual increase in ATPl was observed and it was noted that the highest antibacterial/antiviral effect was maintained compared to other samples. As shown in FIGS. 2 and 3, the reason for this is that the inorganic antibacterial agent (21), the inorganic antiviral agent (22) and the organic antibacterial/antiviral agent (23) are fixed in an exposed state on the superficial layer surface (14a) of the coating films (15 and 35). It is assumed that it is in direct contact with bacteria or viruses that fly with droplets or dust in the outside air and try to cling to the superficial layer surface (14a), and that it has the effect of preventing bacteria or viruses from being fixed on the surface, thus maintaining the superficial layer surface (14a) in a clean condition. Also, in the other sample (B), ATP increased gradually, but the rate of increase here remained somewhat static. The reason for this is that the superficial layer surface of the coating film is formed as a smooth surface containing SiO2 as the main component by the base substance (10A) containing inorganic polysilazane without the antibacterial agent (21), inorganic antiviral agent (22) and organic antibacterial/antiviral agent (23). , that is, it is assumed that the smoothness is higher than the surface smoothness of the sample before coating, and therefore the surface fixation of bacteria or viruses can be prevented to a certain extent. Moreover, in the other sample (C), ATP gradually increased significantly, but the rate of increase here was also higher than that in the previous sample (B). It is assumed that the reason for this is that, unlike the first sample (A) described above, the inorganic antibacterial substance or antiviral substance is not exposed to the superficial layer surface of the coating film and, therefore, its resistance effect on bacteria or viruses is insufficient. Also similarly in other samples (D and E), ATP gradually increased significantly, but the rate of increase here was also higher than that in the previous sample (B). It is assumed that this is because, as in the previous sample (C), the inorganic antibacterial agent or antiviral agent is not exposed to the superficial layer surface of the coating film and, therefore, the resistance effect on bacteria or viruses is not achieved. As explained above, the coating liquid 10 (coating material) according to the present invention comprises a coating agent in which inorganic polysilazane and alkyl silicate condensate are dissolved in an inert solvent at a total concentration of 50 to 80% by mass as base material (10A); It contains the inorganic antibacterial agent (21) added to the base material (10A) at a rate of 0.1% to 5% by mass, and the inorganic antiviral agent (22) added to the base material (10A) at a rate of 0.1% to 20% by mass, and is formed by the inorganic polysilazane and alkyl silicate condensate. By using the created glass coating film as the main material, the inorganic antibacterial agent (21) and the inorganic antiviral agent (22) are fixed stably to the superficial layer surface (14a) of the coating films (15 and 35), and therefore, the article (1) coated with the coating liquid (10) ) (on the coating target) the antibacterial effect and the antiviral effect can remain compatible with each other for a long time. In addition, the coating liquid (10) contains the organic antibacterial/antiviral substance added to the base material (10A) at a rate of 0.1% to 10% by mass, and thus, both the antibacterial effect and the antiviral effect of the article (1) can be increased. In addition, in the coating step of the coating liquid (10), the surface (2) of the article (1) to which moisture is attached is covered with the coating liquid (10), and the moisture that occurs between the components in the coating liquid (10) and the moisture bound to the surface (2) of the article (1). Coating films (15 and 35), which will be the main material containing SiO2 as the main component, are formed on the surface (2) of the article (1) through the chemical reaction, and the antibacterial substance (21) and the antiviral substance (22) are added to the coating films (15 and 35) formed as a result of the chemical reaction. 35) is exposed to the concave part (16b) of the superficial layer surface (14a), and thus, the antibacterial agent (21) and the antiviral agent (22) act directly on various microbes or viruses, and the antibacterial effect and antiviral effect can be increased for a long time. Moreover, the particles of the antibacterial substance (21) and the antiviral substance (22) are arranged in the concave section (16b) of the superficial layer surface (14a) of the coating films (15 and 35) in such a way that the said concave section (16b) can be buried and therefore, the superficial layer The smoothness of the surface 14a can be increased compared to a coating liquid containing only the base substance without additives. Although examples of the present invention are illustrated by drawings, the particular configuration is not limited to the examples, and changes or additions within a range not exceeding the scope of the present invention are also included in the present invention. For example, although inorganic antibacterial agent (21) and inorganic antiviral agent (22) are added to the coating liquid (10) in the examples described above, the present invention is not limited to this application and in the case where a single material has both an antibacterial effect and an antiviral effect, only this It is possible to add the material to the coating liquid.TR TR TR