Methods, systems and apparatuses, including computer programs encoded on computer storage media, are provided for an interactive mirror device. The interactive mirror device comprises a mirror, a display mounted behind the mirror, a processor, a memory including a mirror application, one or more user inputs, and one or more communication modules. The interactive mirror may be in communication with one or more devices and/or services, from which the mirror may receive various types of information. The information may be displayed or otherwise communicated to a user. The interactive mirror may also aggregate and display the information into a form more useful to the user, based on settings or other input from the user. The interactive mirror may replace a mirror door of an existing medicine cabinet, may be installed next to, and physically connected with, an existing medicine cabinet, or may be surface mounted to a wall or recessed into a wall.

Disclosed is a bathroom appliance storage device for conveniently storing and allowing easy access to bathroom appliance such as blow dryers, curling irons, straighteners, hairbrushes and the like. A bathroom appliance storage device includes a rack, wherein the rack includes: at least one ring holder; at least one tube holder; and a handle. A movable support is removably coupled to the rack. At least one track is coupled to the movable support.

A disinfecting vanity mirror includes a substantially enclosed cabinet having top, a bottom, side and rear walls and a mirror panel as the front wall when mounted to form an enclosed space or chamber. The top and bottom walls include passageways to allow vertical air flow through the enclosed space to allow air to enter through the bottom wall to rise and exit through the top wall. Sources of UV light are provided both within and below the cabinet to sanitize the air moving upwardly through the plenum space and below the vanity mirror to expose interior surfaces and exterior surfaces below the cabinet such as sinks and countertops. A controller is programmed to interrupt or discontinue the generation of UV light when a motion detector senses motion in proximity to the mirror and/or in accordance with a programmed sequence of on and off times.

A power supply system for a toilet includes a controller power supply circuit, including an input end electrically connected to an external power supply and an output end. The system includes an assembly driving power supply circuit, including an input end electrically connected to the external power supply and an output end. The power supply system also includes a controller circuit, including a power supply end electrically connected to the output end of the controller power supply circuit and an output end communicably connected to a control end of a switch control circuit of the assembly driving power supply circuit. The system also includes a driving component circuit, including a power supply end electrically connected to the output end of the assembly driving power supply circuit. An output power of the controller power supply circuit is lower than an output power of the assembly driving power supply circuit.

The invention relates to the technical field of smart mirror cabinets, and in particular, to a compact multifunctional bathroom mirror cabinet, including a cabinet body and a cabinet door. The cabinet door is rotatably connected to the cabinet body. The cabinet door is provided with an electric module. The cabinet body is provided with a control module. The electric module is connected with a wireless receiving module, the control module is connected with a wireless transmitting module, and the wireless transmitting module is signal connected with the wireless receiving module. The present invention realizes signal transmission between the cabinet door and the cabinet body in a wireless manner, thereby achieving the effect of omitting some wires and module chips, and making the structure of the present invention more compact.

A mirrored storage cabinet is disclosed, including: a cabinet body formed by a bottom plate and an upper frame, a lower frame, a left frame and a right frame installed at four sides of the bottom plate; and a cabinet door installed at an opening of the cabinet body, wherein a first separating plate and a second separating plate are provided on the bottom plate close to the left frame and the right frame, side mirrors are provided respectively above the left frame and the first separating plate and above the right frame and the second separating plate, LED light strips are installed below the side mirrors via supports on the bottom plate, a division plate is provided between the first separating plate and the second separating plate, and the cabinet door is movably installed at the side edge of the first separating plate.

A metal cabinet with electrically conductive hinges comprises a cabinet body and a cabinet door that are made of an electrically conductive metal. An LED luminous body is disposed in the cabinet door, and at least two electrically conductive hinges for enabling the cabinet door to rotate relative to the cabinet body are disposed between the cabinet door and the cabinet body. Each of the hinges comprises a first hinge body and a second hinge body. The first hinge body is connected to a first electrically conducts wire connecting the first hinge body a power supply. A first outer insulation pad is disposed between the first hinge body and the cabinet body. The second hinge body is connected to a second electrically conductive wire connecting the second hinge body to the LED luminous body. A second outer insulation pad is disposed between the second hinge body and the cabinet door.

An insulating glazing includes at least two substantially parallel glass sheets, which are spaced apart by at least one air- or gas-filled cavity forming a cavity internal to the glazing, a spacer, which is arranged at a periphery of the glass sheets and which keeps the two glass sheets spaced apart, and an adhesive bonding system arranged to fasten the spacer to each glass sheet via two of opposite fastening faces of the spacer, wherein the spacer includes, at least for one side of the glazing, a mirror-function reflective surface on an internal face of the spacer facing the internal cavity of the glazing.

A device including a base section operable for storage or transport of cosmetic items; a compartmentalized storage area including at least one large storage area and at least one small storage area; a primary lid portion that is configured to provide cover for the base section; a mirror appliance disposed on an interior surface of the primary lid portion; a cushioned interior surface; a protective pad that is configured to prevent the stored cosmetic items from making contact with said mirror appliance during transport; a retractable support leg implement; and a chamber section, in which the chamber section comprises at least two open chamber sections being disposed on each side of a bottom portion of the base section, wherein each of the two open chamber sections are configured to house at least two retractable support leg implements.

A disinfecting vanity mirror includes a mirror panel having a top end, a bottom end and lateral edges when mounted on a wall. The mirror is moveably mounted on a hinge along one lateral edge mounted to space the panel from the wall to create a plenum space behind the mirror panel to allow air to enter through the bottom end to rise and exit through the top end. A source of UV light is provided in proximity to the plenum space to sanitize the air moving upwardly through the plenum space. A controller is programmed to interrupt or discontinue the generation of UV light when a motion detector senses motion in proximity to the mirror and/or in accordance with a programmed sequence of on and off times for energizing and de-energizing the source of UV light.