Abstract: A nasal dilator is constructed as a single body truss having a resilient member structure comprising a plurality of overlaid, island-placed, or overlapping resilient members. Methods of mass producing dilator devices, individual resilient members, and overlapped, overlaid, and island-placed resilient member structures are also disclosed.
Abstract: A nasal dilator comprises a laminate of vertical layers each consisting of one or more members or components. The laminated layers form a unitary, or single body, truss featuring horizontal regions adapted to engage outer wall tissues of first and second nasal passages and to traverse the bridge of a nose therebetween. When in use the dilator acts to stabilize and/or expand the nasal outer wall tissues and prevent said tissues from drawing inward during breathing. The dilator includes means to direct its resilient properties comprising one or more interior or exterior material separations, or discontinuity of shape of material, formed in at least one region of the truss and extending through at least one layer of the dilator. Said material separation or discontinuity of shape may comprise an opening, relief cut, slit or notch, and which may be configured to separate or vertically protrude, in part, from the truss when the dilator is in use on the nose of a wearer.
Abstract: A nasal dilator of vertically laminated layers, each consisting of one or more components. The laminated layers form a unitary truss with end regions for engaging outer wall tissues of a user's nasal passages and for traversing the bridge of the nose. The dilator includes means to direct its resilient properties comprising material separations or shape discontinuities formed in at least one region of the truss and extending through at least one layer of the dilator. Said material separations or discontinuities may comprise an opening, relief cut, slit or notch, and may be configured to separate or vertically protrude from the dilator when it is in use. The separations transform the angle of focused delaminating spring biasing forces generated by the resilient layer from primarily peel forces into primarily shear forces, and further redistribute the transformed forces to tissue-engaging surface areas extending outward and beyond the separations.
Abstract: A nasal dilator is constructed as a single body truss having a resilient member structure comprising a plurality of overlaid, island-placed, or overlapping resilient members. Methods of mass producing dilator devices, individual resilient members, and overlapped, overlaid, and island-placed resilient member structures are also disclosed.
Abstract: A nasal dilator comprises a laminate of vertical layers that form a unitary, or single body, truss having horizontal regions adapted to engage outer wall tissues of first and second nasal passages and to traverse the bridge of a nose therebetween. When in use the dilator acts to stabilize and/or expand the nasal outer wall tissues and prevent said tissues from drawing inward during breathing. The dilator includes multiple parallel resilient members or a resilient member having a plurality of component spring fingers extending from a common center. The dilator may further include material separations, or discontinuity of shape of material, formed in at least one region of the truss and extending through at least one layer of the dilator.