An accessory organizer device includes an elongated main body having a plurality of surfaces. A plurality of hooks is secured along one or more surfaces of the main body and can function to engage any number of secondary items such as clothing, jewelry, hats and glasses. The main body includes a layered construction having a rigid core, a padded layer, a decorative layer and a transparent layer. An outer layer is removably secured to the main body and includes a plurality of grommets that are shaped and sized to receive the plurality of hooks.

Methods and apparatus for organizing items according to various aspects of the present invention may comprise a hanger tag system to convey information relating to an item on a hanger. The hanger tag system may comprise, for example, a mount connected to the hanger and an information medium mounted on the mount, wherein the information medium provides information relating to the item. In various embodiments, the hanger tag system further comprises a connector configured to connect the mount to the hanger. In various embodiments, the information medium comprises a labeling surface.

The present disclosure provides a smart clothes drying device and a smart clothes drying method. The smart clothes drying device includes a light intensity sensor, an integrated controller, an umbrella and at least one clothes hanger. The light intensity sensor is to sense light intensity and output a light intensity signal. The integrated controller is to receive the light intensity signal and control opening or closing of the umbrella according to a comparison result of comparing the light intensity signal with a closing light intensity threshold or an opening light intensity threshold in such a manner that the integrated controller controls opening the umbrella when the light intensity signal is greater than the opening light intensity threshold, and the integrated controller controls closing the umbrella when the light intensity signal is less than the closing light intensity threshold.

The present disclosure provides a smart clothes drying device and a smart clothes drying method. The smart clothes drying device includes a light intensity sensor, an integrated controller, an umbrella and at least one clothes hanger. The light intensity sensor is to sense light intensity and output a light intensity signal. The integrated controller is to receive the light intensity signal and control opening or closing of the umbrella according to a comparison result of comparing the light intensity signal with a closing light intensity threshold or an opening light intensity threshold in such a manner that the integrated controller controls opening the umbrella when the light intensity signal is greater than the opening light intensity threshold, and the integrated controller controls closing the umbrella when the light intensity signal is less than the closing light intensity threshold.

In selected examples, a garment includes an article of clothing, a processor, memory storing instructions, biometric and/or environmental sensors configurable and readable by the processor, and a short range radio frequency (RF) transceiver (e.g., a Bluetooth transceiver). When the processor executes the instructions, it may configure the garment to establish an R link with a communication device, enabling the processor to receive from the communication device sensor configuration information, and configure the sensors accordingly. The processor may also collect sensor data, and transmit the data over the RF link from the garment to the communication device. The communication device may be a mobile device, e.g., a smartphone/tablet. The garment may be a master coupled through wired/wireless links to slave garments, and allow the communication device to communicate with the slaves. The communication device may connect the master/slaves to various networks and other computing devices.

In selected examples, a hanger or a garment-storing enclosure couples to an electrically-powered garment, to provide electrical energy for recharging the garment's battery and operating the garment's electronics. The electrical energy may be transferred using low frequency inductive coupling or electromagnetic coupling in the radio frequency range of the spectrum. The hanger/enclosure may include a data interface to the garment, and another data interface to a Wide Area Network (WAN) or another network. Each of the data interfaces may be, e.g., a wireless RF data interface. The garment may include biometric, environmental, and other sensors for collecting data. Through the data interfaces, the hanger/enclosure may enable data flow between the garment and remote devices connected to the WAN. The garment-storing enclosure may be a portable enclosure, such as a garment travel bag. It may also be a relatively-fixed enclosure, such as a closet in an office or a dwelling.

In selected examples, a clothes storage system includes a garment holder designed to receive and store at least one garment, an electromagnetic radiator attached to the garment holder, power circuitry configured to provide electrical drive to the electromagnetic radiator to cause the electromagnetic radiator to radiate radio frequency (RF) power, and a data interface configured to establish short range wireless communication links. The garment holder may be, e.g., a clothes hanger, a garment bag, a travel garment bag, or a walled enclosure such as a closet in a dwelling or an office. The data interface may be a short range RF transceiver, e.g., a Bluetooth transceiver. The radiated RF power is received by the powered garments in/on the garment holder and converted into DC charging power used to recharge batteries of the powered garments. The data interface may allow the powered garments to communicate with external networks, e.g., the Internet.

In selected examples, a hanger couples to an electrically-powered garment, to provide electrical energy to the garment to recharge the battery of the garment. The electrical energy may be transferred from the hanger to the garment using inductive coupling. The electrical energy may also or instead be transferred using contact coupling facilitated by magnet(s) in the interfaces of the hanger system and the garment. The garment may include biometric, environmental, and other sensors to collect data. The hanger system-garment interfaces may provide for data flow between the hanger and the garment. In selected examples, a smart garment may be controlled by a smartphone or another mobile device. The smartphone may control several smart garments, which may be connected in series and/or in parallel, with one of the smart garments being a master connected to the smartphone, and the other garments being slave garments connected to the smartphone through the master.

In selected examples, a hanger couples to an electrically-powered garment, to provide electrical energy to the garment to recharge the battery of the garment. The electrical energy may be transferred from the hanger to the garment using inductive coupling. The electrical energy may also or instead be transferred using contact coupling facilitated by magnet(s) in the interfaces of the hanger system and the garment. The garment may include biometric, environmental, and other sensors to collect data. The hanger system-garment interfaces may provide for data flow between the hanger and the garment. In selected examples, a smart garment may be controlled by a smartphone or another mobile device. The smartphone may control several smart garments, which may be connected in series and/or in parallel, with one of the smart garments being a master connected to the smartphone, and the other garments being slave garments connected to the smartphone through the master.

A variable size marker or sizer for garment hangers is disclosed. A gear-shaped wheel with cogs has various size indicia on each cog, and is inserted into a hanger to display the correct size indicia. The hanger has tabs to retain the sizer in place by mating with slits in the sizer. For example, if a displayed garment is size large, the user chooses the cog with L facing upwardly, and inserts the sizer into the hanger through the bottom of the hanger until the hanger's tabs click into the sizer's slits corresponding with the L. The L is then visible at the top of the hanger. The hanger is made of resilient material to flex outwardly to allow the sizer to be inserted and removed, yet hold the sizer in place when the hanger is in use.