A secondary battery is provided. The secondary battery includes an electrode assembly including a negative electrode sheet, a positive electrode sheet, and a separation membrane; and a heat radiation tape disposed at an external circumferential surface of the electrode assembly. The heat radiation tape includes a heat diffusion layer, and the heat diffusion layer includes at least one of graphite and a metal foil.

The present invention provides an electrode assembly comprising: a radical unit provided with first and second electrodes stacked with a separator therebetween, wherein the first electrode is stacked at the outermost side; and a safety unit disposed on the outermost surface of the radical unit, wherein the safety unit comprises: a first safety plate disposed above the outermost surface of the radical unit; and a first semiconductor material provided between the radical unit and the first safety plate, wherein the first semiconductor material changes from an insulator to a conductor at the first set temperature or more to connect the radical unit to the first safety plate, thereby dissipating heat of the radical unit while conducting the heat to the first safety plate.

The present invention provides an electrode assembly comprising: a radical unit provided with first and second electrodes stacked with a separator therebetween, wherein the first electrode is stacked at the outermost side; and a safety unit disposed on the outermost surface of the radical unit, wherein the safety unit comprises: a first safety plate disposed above the outermost surface of the radical unit; and a first semiconductor material provided between the radical unit and the first safety plate, wherein the first semiconductor material changes from an insulator to a conductor at the first set temperature or more to connect the radical unit to the first safety plate, thereby dissipating heat of the radical unit while conducting the heat to the first safety plate.

An apparatus includes a frame component of a head-mounted device (HMD), an eyepiece, a battery, a processor, a heat pipe, and a hinge. The frame component includes a first compartment, a second compartment, and a channel connecting the first compartment and the second compartment. The heat pipe may extend from the first compartment to the second compartment through a channel and may be configured to transfer heat from the processor to the battery. A rate of heat transfer through the hinge may be greater than a threshold value when the hinge is in an open conformation that configures the frame component to be positioned along the side of the head. The heat transfer through the hinge may be smaller than the threshold value when the hinge is in a folded conformation that configures the frame component to be positioned for storage.

An apparatus includes a frame component of a head-mounted device (HMD), an eyepiece, a battery, a processor, a heat pipe, and a hinge. The frame component includes a first compartment, a second compartment, and a channel connecting the first compartment and the second compartment. The heat pipe may extend from the first compartment to the second compartment through a channel and may be configured to transfer heat from the processor to the battery. A rate of heat transfer through the hinge may be greater than a threshold value when the hinge is in an open conformation that configures the frame component to be positioned along the side of the head. The heat transfer through the hinge may be smaller than the threshold value when the hinge is in a folded conformation that configures the frame component to be positioned for storage.

A system and method for an intelligent hair drying/styling apparatus with user information transmission and storage capabilities is herein provided. The hair drying/styling apparatus houses a control circuit board and an infrared or temperature sensor (or camera) in order detect an individual's hair condition moisture level to determine a user specific, customizable dryer setting. The information detected by the sensor is stored locally, on a proximal Internet-enabled device, or on a remote or cloud-based server and accessed by the hair drying/styling apparatus through a wireless local area network connectivity function. This innovation will enable any number of hair professionals and or end consumers to improve styling and dry time. According to the present invention, energy usage is reduced to enable a more efficient design.

A system and method for an intelligent hair drying/styling apparatus with user information transmission and storage capabilities is herein provided. The hair drying/styling apparatus houses a control circuit board and an infrared or temperature sensor (or camera) in order detect an individual's hair condition moisture level to determine a user specific, customizable dryer setting. The information detected by the sensor is stored locally, on a proximal Internet-enabled device, or on a remote or cloud-based server and accessed by the hair drying/styling apparatus through a wireless local area network connectivity function. This innovation will enable any number of hair professionals and or end consumers to improve styling and dry time. According to the present invention, energy usage is reduced to enable a more efficient design.

A mobile charging station with battery storage for electric vehicles is provided. In one embodiment, a mobile charging station receives a continuous Level 2 charge, converts the continuous Level 2 charge to an intermittent Direct Current Fast Charge (DCFC), and provides the intermittent Direct Current Fast Charge (DCFC) to an electric vehicle for charging. In another embodiment, the mobile charging station has a plurality of charging inputs and charging outputs and provides charge received from one of the plurality of charging inputs to one of the plurality of charging outputs. In yet another embodiment, the mobile charging station is mobile but not integrated in any one vehicle. Other embodiments are provided.

A mobile charging station with battery storage for electric vehicles is provided. In one embodiment, a mobile charging station receives a continuous Level 2 charge, converts the continuous Level 2 charge to an intermittent Direct Current Fast Charge (DCFC), and provides the intermittent Direct Current Fast Charge (DCFC) to an electric vehicle for charging. In another embodiment, the mobile charging station has a plurality of charging inputs and charging outputs and provides charge received from one of the plurality of charging inputs to one of the plurality of charging outputs. In yet another embodiment, the mobile charging station is mobile but not integrated in any one vehicle. Other embodiments are provided.

The present disclosure relates to audio systems for streaming audio data to wireless audio devices from a portable charging case. The portable charging case is arranged to wirelessly charge first and second wireless audio devices as well as stream audio data to the first and second wireless audio devices. The portable charging case can store audio files/audio data within an internal memory, or receive audio data from an external source, e.g., a cable arranged to transmit digital or analog audio data. The portable charging case is further arranged to automatically start streaming audio data to the first and/or second wireless audio devices when a cable is connected to the portable charging case.