An eyewear system including eyeglasses and a case, the eyeglasses having a first lens, a second lens, and a bendable bridge disposed between the first lens and second lens, the bendable bridge having a spring providing a spring force when the bridge is bent from a rest position, the eyeglasses being adapted to move from a wearable configuration in which the first and second lens do not overlap to a stored configuration in which the first and second lenses at least partially overlap, the bendable bridge being bent from its rest position in the stored configuration, the case having an opening through which the eyeglasses pass during insertion and guides sized and configured with respect to the eyeglasses to engage and fold the eyeglasses against spring force of the bridge to the stored configuration during insertion of the eyeglasses through the opening and into the case.

Protective eyeshields have two lenses, which are interconnected at their proximal ends by an adjustable nose-bridge and are releasably connectable at their distal ends by two conjugate connecting straps. The lenses have a longitudinal convex curvature so that they follow the contours of the wearer's face. They are substantially trapezoidal in shape, tapering from the proximal end to the distal end. The lenses are made of a light-weight semi-rigid plastic, such as plexi-glass, and may be clear transparent or tinted. Plastic foam padding is provided along the longitudinal edges of the lenses to cushion the area of contact between the lenses and the wearer's face. The weight of the lenses is support from below by four support struts, two of which are nose supports and two which are cheek supports. Each of the support struts integrally comprises a stem element and a contact pad element.

A slip-resistant eyewear system comprising an eyewear frame generally comprises a nosepiece comprising a nosepiece material configured to couple to a bridge of an eyewear frame. The frame comprises first and second hinges coupled to the eyewear frame which are also coupled to first and second spring-loaded tension adjusters. First and second bows are coupled to first and second tension adjusters. A first bow extension element is coupled to the first bow and comprises a first fastening element at a first end of the first bow extension element and a second bow extension element is coupled to the second bow and comprises a second fastening element at a first end of the second bow extension element that is configured to mate with the first fastening element to secure the first and second bow extension elements together.

Goggles, goggle frames, and methods for adjusting a fit of a goggle frame are disclosed. In an example goggle, the goggle includes a frame and a lens. The frame includes a lens receiving portion and a face contact portion. The face contact portion includes a nose recess including an adjustable member for changing a contour of the face contact portion. The lens is configured to be mounted to the lens receiving portion. In an example goggle frame, the goggle frame includes a lens opening for mounting a lens thereto and a nose recess portion including a fit adjustment member. The fit adjustment member is configured to be deformed from an undeformed shape to a deformed shape and to retain the deformed shape.

A nose support assembly for a spectacle frame, includes two nose support elements (3), known as nose pads, and, for each nose pad, a mounting element (2) for the nose pad, known as the nose pad holder. Each nose pad (3) and the corresponding nose pad holder (2) have connecting elements (1) for connecting one to the other, the connecting elements being designed to allow the nose pad (3) to move angularly with respect to the nose pad holder (2). A frame equipped with such a nose support assembly is also described.

Nosepiece for eyeglass frames which comprises: a plate intended to abut against the nose of a user; a support arm for connecting the plate to the frame of eyeglasses; a cup which is extended as a prolongation of the support arm; an appendage which is projectingly extended from the rear face of the plate and is housed within the cup with two lateral faces thereof facing two lateral walls of the cup; coupling means for retaining the appendage housed within the cup. The appendage comprises a convex portion which is susceptible of rotating with respect to the cup with the surface of the convex portion in contact and in sliding-with-friction relation with the internal surface of the cup, in order to maintain the plate in the reached angular position.

A goggle structure having a flip-up function and capable of covering eyeglasses includes a first lens, a second lens, two temple units, and two soft sealing pads. The first lens has two lateral sides each provided with a first coupling portion and extended with a transparent lateral window portion. The second lens is pivotally connected to the first lens. Each temple unit includes an adapter block that is rotatable leftward and rightward with respect to the first lens and a temple that is rotatable upward and downward with respect to the adapter block. The soft sealing pads are detachably coupled to the first lens. The inner side of the first lens defines an accommodating space for accommodating the eyeglasses the user wears in the first place, with the first lens covering the eyeglasses, so the user can wear the goggles as well as the eyeglasses during work or other activities.

Protective eyeshields have two lenses, which are interconnected at their proximal ends by an adjustable nose-bridge and are releasably connectable at their distal ends by two conjugate connecting straps. The lenses have a longitudinal convex curvature so that they follow the contours of the wearer's face. They are substantially trapezoidal in shape, tapering from the proximal end to the distal end. The lenses are made of a light-weight semi-rigid plastic, such as plexi-glass, and may be clear transparent or tinted. Plastic foam padding is provided along the longitudinal edges of the lenses to cushion the area of contact between the lenses and the wearer's face. The weight of the lenses is support from below by four support struts, two of which are nose supports and two which are cheek supports. Each of the support struts integrally comprises a stem element and a contact pad element.

Provided is an eyeglass frame with a symmetrical structure. The eyeglass frame includes an earpiece frame, a main body, a hinge, and a support frame. The earpiece frame has a bar-shaped structure in which a width and an angle thereof vary according to the length thereof to be placed on the ear of a user. The main body is connected to the earpiece frame through a hinge, serves as a pivot that pivots on the hinge, and has an inner circumference of a closed curve receiving a lens. The hinge allows the earpiece frame to be inwardly folded toward the main body through pivoting of a predetermined angle. The support frame is disposed under the main body along an outer circumference of the main body and is spaced from the main body by a predetermined interval.

Systems and method describe an actuator control system for controlling an intelligent actuated nose bridge on a pair of wearable glasses. The actuator control system receives a set of measurement data corresponding to a length of the nose bridge, generates a predicted set of measurement data for the length of the nose bridge, transmits the predicted set of measurement data to pneumatic actuators coupled to the nose bridge, captures a first set of images of the nose bridge, generates an augmented set of measurement data for the nose bridge, generates an adjusted set of measurement data based on the predicted set of measurement data and the augmented set of measurement data, and transmits the adjusted set of measurement data to the pneumatic actuators coupled to the nose bridge.