A dehaze and bacteriostatic film includes a substrate material layer and a composite surface plasmon layer formed on the substrate material layer. The composite surface plasmon layer includes a particle stacked film layer and a particle suspension layer located on the substrate material layer, and the particle stacked film layer and the particle suspension layer jointly generate a composite surface plasmon wave. Accordingly, the composite surface plasmon wave is excited by visible light, so that different types of surface plasmon waves generated by the structures resonate and multiply with each other. The different surface plasmon waves add up to generate electromagnetic field intensity capable of dissociating spatial materials at a certain distance, such as water vapor to be partially ionized which is rich in hydroxide ions with effects of dehazing and inhibiting growth of bacteria.

[Problem to be Solved]

To provide a cosmetics container or the like capable of reducing bacteria in cosmetic product.

[Solution]

A container main body 20 of the cosmetics container of the present invention is configured of a main body portion 22 that configures the basic structure of the container main body 20 and an inner surface portion 24 that configures the inner surface of the container main body 20. The inner surface portion 24 is configured as a sterilizing portion in which metal fine particles having an effect of reducing bacteria are dispersed in a resin and bacteria are reduced by the action of the fine particles. The fine particles are configured so as not to be exposed on the surface of the inner surface portion 24. The type of metal configuring the sterilizing portion is defined according to the type of bacteria that is assumed to become a problem at each position on the inner surface portion 24.

[Problem to be Solved]

To provide a cosmetics container or the like capable of reducing bacteria in cosmetic product.

[Solution]

A container main body 20 of the cosmetics container of the present invention is configured of a main body portion 22 that configures the basic structure of the container main body 20 and an inner surface portion 24 that configures the inner surface of the container main body 20. The inner surface portion 24 is configured as a sterilizing portion in which metal fine particles having an effect of reducing bacteria are dispersed in a resin and bacteria are reduced by the action of the fine particles. The fine particles are configured so as not to be exposed on the surface of the inner surface portion 24. The type of metal configuring the sterilizing portion is defined according to the type of bacteria that is assumed to become a problem at each position on the inner surface portion 24.

The invention provides a method for removing haze and inhibiting bacteria. First preparing a dehaze and bacteriostatic film comprising a substrate material layer and a composite surface plasmon layer. The composite surface plasmon layer includes a particle stacked film layer and a particle suspension layer which jointly generate a composite surface plasmon wave. Then, exciting the composite surface plasmon wave by visible light to resonate different types of surface plasmon waves generated by the composite surface plasmon wave, and adding up energy of the surface plasmon waves to ionize water and oxygen. Since energy of the generated electromagnetic field can ionize substances at a certain distance, such as dissociated water is rich in hydroxide ions that performs dehaze and bacteriostatic effect. The dehaze and bacteriostatic effect can be enhanced through increasing in thickness (number of layers) of the particle stacked film layer and the particle suspension layer.

The invention provides a method for removing haze and inhibiting bacteria. First preparing a dehaze and bacteriostatic film comprising a substrate material layer and a composite surface plasmon layer. The composite surface plasmon layer includes a particle stacked film layer and a particle suspension layer which jointly generate a composite surface plasmon wave. Then, exciting the composite surface plasmon wave by visible light to resonate different types of surface plasmon waves generated by the composite surface plasmon wave, and adding up energy of the surface plasmon waves to ionize water and oxygen. Since energy of the generated electromagnetic field can ionize substances at a certain distance, such as dissociated water is rich in hydroxide ions that performs dehaze and bacteriostatic effect. The dehaze and bacteriostatic effect can be enhanced through increasing in thickness (number of layers) of the particle stacked film layer and the particle suspension layer.

This disclosure includes a description of luggage devices configured to provide convenient access to sanitizers. The luggage device can include a receptacle having an opening to receive a sanitizer container therein. The luggage device can include a support that is translated or moved within the receptacle by way of a push-to-release mechanism. The push-to-release mechanism can translate or move the support between a deployed position in which the sanitizer container is at least partially exposed outside the receptacle and a stowed position in which the sanitizer container is disposed inside the receptacle. The luggage device can include a dispenser that enables the user to dispense sanitizer from a sanitization container in the receptacle.

The present invention relates to a puff sterilization patch and, particularly, to a puff sterilization patch which is manufactured in the form of a net or fabric by using yarns made of copper having sterilizing power and can be attached to a cosmetic container so as to sterilize a puff. To this end, the present invention comprises: a pad layer formed by weaving wefts and warps into a net, wherein the wefts mainly comprise yarns made of copper and are arranged at regular intervals, and the warps mainly comprise yarns made of a synthetic resin material and are arranged at regular intervals: and an adhesive layer provided on the underside surface of the pad layer.

The present invention relates to a puff sterilization patch and, particularly, to a puff sterilization patch which is manufactured in the form of a net or fabric by using yarns made of copper having sterilizing power and can be attached to a cosmetic container so as to sterilize a puff. To this end, the present invention comprises: a pad layer formed by weaving wefts and warps into a net, wherein the wefts mainly comprise yarns made of copper and are arranged at regular intervals, and the warps mainly comprise yarns made of a synthetic resin material and are arranged at regular intervals: and an adhesive layer provided on the underside surface of the pad layer.

A metal ionic antimicrobial surface configured for external use on a surface location in an indoor environment. A surface structure includes a pair of opposed major surfaces, one surface forming an exposed layer having a pattern of conductive strips and corresponding insulative spacings with a power pod structure secured to the surface structure. The power pod structure houses a battery and a power control circuit electrically connected to the conductive strips. In embodiments, the battery has an amp-hour capacity of 150-1500 mAh, an average width of each conductive strip of copper and silver metallic ions and each insulative spacing is between 0.1 to 0.5 millimeters, and the power control circuit includes a voltage booster circuit that maintains a constant low voltage of 2.5V-4.5V. The antimicrobial surface provides a replaceable period of at least a month of generally continuous and consistent reduction in microbial contaminants when positioned on surface locations that correlate to a zone of high impact regions for transmission pathways of microbial contaminants. In embodiments, a continuous reduction of at least 99% in microbial contaminants and at least a 2× reduction in other contaminated surfaces in a zone within the indoor environment proximate the antimicrobial surface is achieved over the replaceable period.

A metal ionic antimicrobial surface configured for external use on a surface location in an indoor environment. A surface structure includes a pair of opposed major surfaces, one surface forming an exposed layer having a pattern of conductive strips and corresponding insulative spacings with a power pod structure secured to the surface structure. The power pod structure houses a battery and a power control circuit electrically connected to the conductive strips. In embodiments, the battery has an amp-hour capacity of 150-1500 mAh, an average width of each conductive strip of copper and silver metallic ions and each insulative spacing is between 0.1 to 0.5 millimeters, and the power control circuit includes a voltage booster circuit that maintains a constant low voltage of 2.5V-4.5V. The antimicrobial surface provides a replaceable period of at least a month of generally continuous and consistent reduction in microbial contaminants when positioned on surface locations that correlate to a zone of high impact regions for transmission pathways of microbial contaminants. In embodiments, a continuous reduction of at least 99% in microbial contaminants and at least a 2× reduction in other contaminated surfaces in a zone within the indoor environment proximate the antimicrobial surface is achieved over the replaceable period.