Swimming goggles includes a main body and a top anchor. The main body includes a lens unit, at least one gasket, and a strap. The at least one gasket is made of soft material and is disposed on a rear side of the lens unit for abutting a face of a wearer. The strap is coupled with the lens unit. A top anchor disposed on top of the main body. The top anchor includes a front end connected to the top portion of the lens unit and extends upward and rearward. Top anchor is configured to abut an upper portion and a rear portion of a head of the wearer wearing the swimming goggles. Thus, the swimming goggles can withstand the water resistance to improve the wearing stability while preventing water leakage into the swimming goggles.

A cosmetic lash protection device comprising a pair of eye members. Each eye member including a rim defining an interior volume configured to allow the cosmetic lashes to move freely therein. An adhesive disposed on each rim, wherein the adhesive is configured to removably attach the system to a user's face. Systems and methods are provided.

A wireless communications system for determining and conveying swimming metrics to swimmers and triathletes during swimming activity. The swimming metric communication system comprises a smartwatch for determining swim metrics and a head-worn device with an integrated headphone, headphone jack, or wireless headphone transmitter. The smartwatch and head-worn device utilize a Bluetooth Low Energy (BLE) connection to communicate voiced swim metrics to the user. For example, various voiced data segments are preloaded on the head-worn device and associated with unique low-bit codes, respectively. The BLE connection is used to transmit certain low-bit codes to trigger respective voiced data segments. A transmission connection between the smartwatch and headphone, and vice-versa, is established when the user's hand is out of the water (recovery) and/or when the hand passes near the face underwater (pull). Once a connection is established and codes are received, the headphone decodes the sequence of codes and plays a respective voiced swimming metric without interruption to swimming activity. The head-worn device may include sensors for improving the accuracy of the swim metrics or for determining additional swim metrics, which are communicated to the smart watch for display.

The present invention is new art with a new function and is comprised of goggles or a mask that has an ornamental design on the lens component of the goggles or mask.

The present invention provides materials and methods for forming an interface between an appliance and living tissue using a foamed elastomeric material which contacts the tissue or similar surfaces. The elastomeric material is in the form of a durable and washable material that when applied to living tissue or similar surfaces displaces and flows in to non-conforming areas creating an air and/or water tight seal that substantially returns to an original shape when removed from the contact surface. The appliance may also include structural elements designed to optimize comfort, compliance and seal achieved through minimizing the pressure variation along the contact surface of the therapy device.

The invention relates to spectacles, systems and methods for visibility enhancement, including by glare suppression. The spectacles, systems and methods for visibility enhancement includes spectacles and a spectacle lens having a liquid crystal cell (LC), the transmission (TR) of which may be varied by a suitable control and the liquid crystal cell (LC) designed so that the transmission (TR) of the liquid crystal cell (LC) may be switched between high and low transmission states. The liquid crystal cell (LC) includes a control for regulating the times of the state of high transmission (T.sub.on) of the liquid crystal cell (LC) such that the temporal position of the times of the high transmission state (T.sub.on) within a period of times of the high transmission state (T.sub.on) and times of the low transmission state (T.sub.off) may be altered continuously or discontinuously; and/or the duration of a period of times of the high transmission state (T.sub.on) and times of the low transmission state (T.sub.off) may be altered continuously or discontinuously. Such changes may be determined by a secret coding key.

An adjustable eyewear restraint comprises a first strap having a first adjustment end and a first eyewear coupling end, and a second strap having a second adjustment end and a second eyewear coupling end. The straps are slidably and frictionally engageable to one another to allow adjustment of a length of the restraint by moving adjustment ends of the straps relative to each other. The straps can be slidably interwoven to each other about opening(s) of respective adjustment ends. The opening(s) slidably receive an opposing strap. A strap has a loop, coupleable to eyewear, that comprises first and second edges attached together to form an attachment portion substantially in-line with the first edge. A frictional element is frictionally and slidably coupleable to an earpiece to retain the loop and allow adjustment of a length of an eyewear retainer. Associated systems and methods are provided.

A wearable computing device that is secured or attached to a resilient strap, the resilient strap sized to fit around at least a part of a circumference of a human head. The device has a waterproof storage volume housing a plurality of sensors. The wearable computing device may calculate a plurality of swimming metrics based at least partly on data received from the at least one sensor. The wearable computing device may include a wireless communication subsystem secured to the resilient strap within the waterproof storage volume and may transmit at least one of the calculated plurality of swimming metrics to at least one computing device via the wireless communication subsystem. The wearable computing device may include at least one user output component and may present an indication of at least one of the calculated plurality of swimming metrics at the at least one user output component for communication to the user. The indication may be audio played in an ear piece connected to the strap, or may be visually displayed on a display in an eye goggle portion of the strap.

A training aid for a swimmer includes a housing. The housing is sealed so that the housing is water tight. A coupler is coupled to the housing and is configured to couple to a swimmer's goggles to couple the housing to the goggles. A power module, a microprocessor, and a sensor are coupled to and positioned in the housing. An indicator is coupled to the housing. The microprocessor is operationally coupled to the power module. The sensor and the indicator are operationally coupled to the microprocessor. The sensor is configured to detect motion of the housing so that the microprocessor is positioned to determine a speed of the swimmer and to compare performance values of the swimmer relative to target values. The microprocessor is positioned to selectively signal the indicator to notify the swimmer of a difference between the performance values and the target values.

A training aid for a swimmer includes a housing. The housing is sealed so that the housing is water tight. A coupler is coupled to the housing and is configured to couple to a swimmer's goggles to couple the housing to the goggles. A power module, a microprocessor, and a sensor are coupled to and positioned in the housing. An indicator is coupled to the housing. The microprocessor is operationally coupled to the power module. The sensor and the indicator are operationally coupled to the microprocessor. The sensor is configured to detect motion of the housing so that the microprocessor is positioned to determine a speed of the swimmer and to compare performance values of the swimmer relative to target values. The microprocessor is positioned to selectively signal the indicator to notify the swimmer of a difference between the performance values and the target values.