Discussed is a battery property measurement apparatus including a main body made of an insulative material, the main body being configured to be put on a hand of a user; and a measurement unit installed at a portion of the main body at which a finger of the user is located, the measurement unit being configured to contact at least a portion of respective opposite ends of a battery, the measurement unit being electrically connected to the battery when the user push on the battery using the finger in a state in which the battery is coupled to the measurement unit.

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.

The exercise performance monitoring glove consists of a pair of flexible gloves that have embedded pressure sensor arrays to measure hand pressure applied to them during physical activities such as exercise. Each glove sends its pressure data in a real-time format using an embedded wireless RF transmitter to the opposite glove. The gloves then compare the pressures and provide feedback through a user selectable choice of either audio, visual or vibratory methods. Audio feedback is provided to earbuds using typical connection means such as Bluetooth connection to a smartphone or remote device having an exercise performance monitoring app. Visual feedback is provided in several possible modes such as text, color, and graphics using an embedded wraparound flexible display screen. Vibratory feedback is provided using embedded vibration devices inside the gloves. Once a specific feedback mode is selected using the performance monitoring app, the user will know whether the gloves are in a balanced or unbalanced state. Using this real-time feedback allows the user to make corrections in the hand grip forces to achieve a balanced state. The gloves can be used in a wide variety of situations such as exercise, sports, and for medical rehabilitation where body balance is important.

The inventive glove provides a work glove that detects the presence of AC voltage without compromising its usability as a work glove. Embodiments of the inventive glove include monopole aerials extending into the fingers of the glove. A thin flexible dielectric layer sits between the aerials and inside of the glove, acting as an electrical barrier between the aerials and the user's hand. The aerials are connected to conventional voltage detector circuitry on a circuit board located on the back of the glove. The circuit board is grounded to the user's wrist, which enhances the circuitry's ability to detect the presence of nearby AC voltage at a safe distance.

A medical tool for fingertip of the present invention has a resin layer that emits red fluorescence or near-infrared fluorescence, and is used by putting it on a fingertip. More specifically, the medical tools for fingertip 1A to 1E have a finger cot shape and an opening portion 2 from which the ball of the finger is exposed when put on, and are formed of a resin that emits red fluorescence or near-infrared fluorescence. Alternatively, the medical tools for fingertip 1F and 1G have a globe shape, and a printing layer 8, 9 that is formed of a resin that emits red fluorescence or near-infrared fluorescence on or around the ball of the finger thereof. Further alternatively, the medical tools for fingertip 1H and 1I are a sticker-like medical tool having an adhesive layer provided to one surface of the resin layer that emits red fluorescence or near-infrared fluorescence, and have a size that allows it to be attached to the ball of the finger. When the medical tools for fingertip are put on the tip of a finger of a surgeon used for palpation of a living body, the position of an affected site which has been specified from the mucosal side by the palpation can be accurately specified from the serosal side.

A hand protection method is provided that detects hand self-motion information and relative motion information between the hand and surrounding objects. The method also contemplates evaluating a risk level of the hand injured by surrounding objects according to the detected self-motion information and the detected relative motion information. An alarm is sounded if the risk rises above a predetermined risk level.

An all-fabric iontronic supercapacitive pressure sensing device utilizing a novel iontronic nanofabric as the sensing element is disclosed. The sensing device can be applied in several various wearable health and biomedical applications on complex body topologies. As an alternative to conventional flexible sensors, the all-fabric iontronic pressure sensor provides an ultrahigh device sensitivity with a single Pascale resolution. The device also allows rapid mechanical responses (in the milliseconds range) for high-frequency biomechanical signals, e.g., blood pressure pulses and body movements. The fabrication process for the device is low-cost highly compatible with existing industrial manufacturing processes.

A method is provided for measuring the temperature of a tire. The method comprises (a) providing a temperature measuring instrument which is equipped with a plurality of temperature probes, wherein each of the plurality of temperature probes sense the temperature of a surface they come into contact with; (b) providing a software program installed on a mobile technology platform, wherein said mobile technology platform is equipped with a display and is in wireless communication with the temperature measuring instrument, and wherein the software program operates in conjunction with said mobile technology platform and the temperature measuring instrument to capture temperature readings sensed by the plurality of temperature probes; (c) receiving user input from a user of said mobile technology platform, the user input specifying tire parameters for a set of tires on which temperature readings are to be captured, wherein the tire parameters identify (a) a set of tires, (b) a vehicle that the set of tires are to be used in conjunction with, and (c) a track at which the vehicle will be operated when the temperature readings are captured; (d) creating a tire temperature measurement record from said user input; (e) capturing a plurality of temperature readings from said temperature measuring instrument after said plurality of temperature probes have been placed into contact with the external surface of at least one member of said set of tires; (f) adding the captured temperature readings to the tire temperature measurement record such that each captured temperature reading is associated with a tire, from the set of tires, that the captured temperature reading originated from; and (g) displaying, on the display of the mobile technology platform, a summary of temperature readings captured for a vehicle.

A garment and/or garment system with health-monitoring (e.g., cardiovascular monitoring) capability, substantially as shown in and/or described in connection with at least one of the figures, as set forth more completely in the claims.