Disclosed and described herein are systems and methods of energy generation from fabric electrochemistry. An electrical cell is created when electrodes (cathodes and anodes) are ‘printed’ on or otherwise embedded into fabrics to generate DC power when moistened by a conductive bodily liquid such as sweat, wound, fluid, etc. The latter acts, in turn, as the cell's electrolyte. A singular piece of fabric can be configured into multiple cells by dividing regions of the fabric with hydrophobic barriers and having at least one anode-cathode set in each region. Flexible inter-connections between the cells can be used to scale the generated power, per the application requirements.

The method comprises providing a textile patch (103) comprising a biosensing unit (101a, b). The method comprises providing a controller (105) for controlling the biosensing unit (101a,b) ono a surface of the textile patch (103). The method comprises attaching the textile patch (103) to a textile panel (107) to form the biosensing textile. The controller (105) is sandwiched between the textile patch (103) and the textile panel (107). The textile panel (107) may be attached to the inside of a garment (200). A garment and textile panel are also provided.

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.

An embodiment of a robotic fabric has a first fabric layer and an actuator that is configured to have a first state and a second state. A property of the first fabric layer is different when the actuator is in the first state as compared to the property of the first fabric layer when the actuator is in the second state.

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 massaging garment assembly includes a body suit that is wearable on a user's body to cover areas of the user's body generally associated with massage therapy. A plurality of first massage balls is each of movably embedded into the body suit to massage the user's body at common massage point. A plurality of sets of second massage balls is each movably embedded into the body suit to massage the user's body at the common massage points. A plurality of first massage rollers is each of the first massage rollers is movably embedded into the body suit to massage the user's body at the common massage points. A plurality of sets of second massage rollers is each movably embedded into the body suit to massage the user's body at the common massage points.

Provided is a soft sensor embedded glove including an upper inside skin pattern, a soft sensor module coupled to at least a surface of the upper inside skin pattern, and including at least one soft sensor formed on a joint portion of a finger to measure flexion and extension of the finger, and an outside skin coupled to the upper inside skin pattern and exposed to outside, wherein, in the upper inside skin pattern, a width of a region to which the at least one soft sensor is coupled is less than a width of another region.

A device and system for monitoring breast milk volume comprising a sensing module attached to a bra. The sensing module can include a processing unit configured to receive, store, and process readings measured by the sensing components of the module. The processing unit can be connected to a wireless transmitter that can be configured to transmit recorded and stored readings from the sensing module to a mobile device. The mobile device can display the transmitted data and further process the data to enable visualization of trends in the collected data.

An apparatus for an armor system includes a housing case, an interior ballistic panel, a frame, a power source, and a control unit. The housing case includes a top shell and a bottom shell, where the top shell is removably secured to the bottom shell, forming a cavity. The interior ballistic panel is removably arranged within the cavity between the top shell and the bottom shell. The frame is arranged within the cavity between the top shell and the interior ballistic panel, the frame including a compartment. The power source is arranged within the compartment of the frame, and the control unit is communicatively connected to the power source to manage operation of the power source.

Embodiments of the present the disclosure relate to apparatuses, systems, and methods for flexible electronic panels that can be incorporated into various garments. In an exemplary embodiment, a garment comprising a plurality of panels. In aspects, a first panel is a unitary panel extending from a first appendage of the garment to a second appendage of the garment. Additionally, at least the first panel comprises at least one conductive trace and wherein the remaining plurality of panels form the remainder of the garment.