The disclosure relates to on-ear headphones comprising at least one ear-cushion, the at least one ear-cushion defining an ear-surface configured to interface with a user's ear when the headphones are worn by the user, the ear-surface comprising a perforated area, the perforated area comprising a plurality of staggered elongated perforations.

A personal acoustic system and flexible mount for the same are disclosed. The flexible mount is comprised of an elastomeric material. The personal acoustic system further includes a band comprising a first mount and an earpiece comprising a second mount. An acoustic element is housed within the earpiece. The elastomeric mount is positioned intermediate the first mount and the second mount to flexibly connect the band to the earpiece.

An earbud includes a housing that includes a driver assembly positioned within the housing forming a front volume in front of the driver and a back volume behind the driver. An acoustic insert is positioned behind the driver assembly and attached to an interior surface of the housing such that it forms a bass channel that is routed from the back volume to a vent in the housing.

A method for manufacturing a hearing device is disclosed. The hearing device comprises a speaker, a first chamber, and a sound channel arranged between the first chamber and the surroundings of the hearing device or a second chamber. An element of a thermoplastic material being in a solid state is arranged in the sound channel. A laser light is applied to the element to thereby activate the element to change from the solid state to a liquid state. The element then changes from the solid state to the liquid state filling out a cross-section of the sound channel and thereby sealing the sound channel. Finally, cooling of the element is allowed leading to a change of the element from the liquid state to solid state while filling out the cross-section of the sound channel.

The present disclosure relates to an earpiece for an ear. The ear comprises a concha cavity at least partially delimited by a concha floor, a concha side wall and a concha ceiling. The earpiece comprises a peripheral skirt comprising a positioning skirt portion which in turn comprises an outer skirt surface and an inner skirt surface, wherein a transition from the outer skirt surface to the inner skirt surface occurs at a skirt edge. The skirt edge extends at least partially circumferentially around a central axis of the earpiece, wherein the earpiece is adapted to be moved to a use position, at least partially within the concha cavity, in a direction parallel to the central axis, during insertion of the earpiece into the ear. When the peripheral skirt is in a non-influenced condition, at least a portion of the inner skirt surface faces the central axis.

An acoustic device with an open audio device structure that is configured to be carried on the head or upper torso of a user, a housing carried by the open audio device structure, the housing having opposed first and second ends, a flat diaphragm in the housing and comprising a front face and a rear face, the diaphragm configured to radiate front acoustic radiation from its front face and rear acoustic radiation from its rear face, wherein the front and rear acoustic radiations are out of phase, structure that supports the diaphragm such that the diaphragm can move relative to the housing, a primary magnet adjacent to the rear face of the diaphragm, a magnetic circuit that defines a path for magnetic flux of the primary magnet, a voice coil that is exposed to the magnetic flux and is configured to move the diaphragm up and down along a radiation axis that is normal to the front face of the diaphragm, and first and second sound-emitting outlets in the housing, wherein the first sound-emitting outlet is in or proximate the first end of the housing and is acoustically coupled to the front face of the diaphragm so as to emit front acoustic radiation into an acoustic space, and wherein the second sound-emitting outlet is in or proximate the second end of the housing and is acoustically coupled to the rear face of the diaphragm so as to emit rear acoustic radiation into the same acoustic space.

The present disclosure relates to an earpiece for an ear. The ear comprises a concha cavity at least partially delimited by a concha floor, a concha side wall and a concha ceiling. The earpiece comprises a peripheral skirt comprising a positioning skirt portion which in turn comprises an outer skirt surface and an inner skirt surface, wherein a transition from the outer skirt surface to the inner skirt surface occurs at a skirt edge. The skirt edge extends at least partially circumferentially around a central axis of the earpiece, wherein the earpiece is adapted to be moved to a use position, at least partially within the concha cavity, in a direction parallel to the central axis, during insertion of the earpiece into the ear. When the peripheral skirt is in a non-influenced condition, at least a portion of the inner skirt surface faces the central axis.

An earpiece includes an earbud that supports at least one electrode, and an ear tip that includes a hydrogel. The ear tip is configured to be coupled to the earbud such that the hydrogel overlies the at least one electrode and such that the hydrogel is disposed between the at least one electrode and the user's skin when the earpiece is worn.

The present disclosure relates to an earpiece for an ear. The ear comprises a concha cavity at least partially delimited by a concha floor, a concha side wall and a concha ceiling. The earpiece comprises a peripheral skirt comprising a positioning skirt portion which in turn comprises an outer skirt surface and an inner skirt surface, wherein a transition from the outer skirt surface to the inner skirt surface occurs at a skirt edge. The skirt edge extends at least partially circumferentially around a central axis of the earpiece, wherein the earpiece is adapted to be moved to a use position, at least partially within the concha cavity, in a direction parallel to the central axis, during insertion of the earpiece into the ear. When the peripheral skirt is in a non-influenced condition, at least a portion of the inner skirt surface faces the central axis.

A cartilage conduction system may include (1) a transducer that generates mechanical energy and (2) a functionally graded material (FGM) interface dimensioned to be coupled between the transducer and cartilage located on an outer ear of a user, wherein the FGM interface (1) exhibits a gradation of at least one characteristic from one side of the FGM interface to another side of the FGM interface and (2) facilitates transferring the mechanical energy across the gradation of the characteristic from the transducer to the cartilage. Various other systems and methods are also disclosed.