Described is a human-ear-wearable apparatus having a housing, which contains electronic and auditory components for conveying sound into a human hear. An inflatable mounting system is configured to secure the housing to the human ear. The mounting system includes an elastomeric bladder configured to inflate into a customizable counterpart shape of portions of the user's Concha and Meatus areas of a particular user's ear. A pump, coupled to the housing, is configured to pass air through an opening in the housing to the elastomeric bladder. Inflation of the bladder, via the pump, is controllable by a user to form a customized fit of the mounting system's bladder to the Concha and Meatus areas of the user's ear. One or more speakers may be encased in the elastomeric bladder. For example, a dual-hybrid speaker arrangement is described with a cone speaker and a balanced-armature driver embedded in the bladder.

Described is a human-ear-wearable apparatus having a housing, which contains electronic and auditory components for conveying sound into a human hear. An inflatable mounting system is configured to secure the housing to the human ear. The mounting system includes an elastomeric bladder configured to inflate into a customizable counterpart shape of portions of the user's Concha and Meatus areas of a particular user's ear. A pump, coupled to the housing, is configured to pass air through an opening in the housing to the elastomeric bladder. Inflation of the bladder, via the pump, is controllable by a user to form a customized fit of the mounting system's bladder to the Concha and Meatus areas of the user's ear. One or more speakers may be encased in the elastomeric bladder. For example, a dual-hybrid speaker arrangement is described with a cone speaker and a balanced-armature driver embedded in the bladder.

The present disclosure discloses a loudspeaker apparatus. The loudspeaker apparatus may include an ear hook including a first plug end and a second plug end, a core housing for accommodating an earphone core, and a circuit housing for accommodating a control circuit or a battery. The ear hook may be surrounded by a protective sleeve which is made of an elastic waterproof material. The core housing may be fixed to the first plug end and elastically abutted against the protective sleeve. The core housing may include a housing panel facing human body and a housing back panel opposite to the housing panel. When the vibration frequencies of the housing panel and the housing back panel is within a range of 2000 Hz to 3000 Hz, an absolute value of a difference between the first phase and the second phase may be less than 60 degrees.

A sound-producing balanced armature receiver, as disclosed, includes a receiver housing with a first internal volume, a second internal volume, and a sound outlet. The receiver includes a first diaphragm separating the first internal volume into a first front volume and a first back volume and a second diaphragm separating the second internal volume into a second front volume and a second back volume. The receiver also includes a motor inside the first back volume of the housing such that the motor includes an armature mechanically coupled to both the first diaphragm and the second diaphragm, an acoustic seal between the first front volume and the second back volume such that the acoustic seal accommodates the mechanical coupling of the armature to the second diaphragm while providing acoustic separation between the first internal volume and the second internal volume, and a back-volume increasing structure attached externally to the housing and acoustically coupled with the second back volume to provide additional volume to the second back volume.

A sound-producing balanced armature receiver, as disclosed, includes a receiver housing with a first internal volume, a second internal volume, and a sound outlet. The receiver includes a first diaphragm separating the first internal volume into a first front volume and a first back volume and a second diaphragm separating the second internal volume into a second front volume and a second back volume. The receiver also includes a motor inside the first back volume of the housing such that the motor includes an armature mechanically coupled to both the first diaphragm and the second diaphragm, an acoustic seal between the first front volume and the second back volume such that the acoustic seal accommodates the mechanical coupling of the armature to the second diaphragm while providing acoustic separation between the first internal volume and the second internal volume, and a back-volume increasing structure attached externally to the housing and acoustically coupled with the second back volume to provide additional volume to the second back volume.

The present embodiment relates to a double-faced display device generating sound by directly vibrating a display panel and includes: a first display panel and a second display panel disposed at the front and rear surface thereof, respectively; a single sound generating actuator connected to the first display panel and the second display panel to simultaneously vibrate the first display panel and the second display panel and thus generate sound; and a support part configured to support the sound generating actuator, the first display panel, and the second display panel. The present embodiment does not require a separate speaker and thus can achieve a thin or slim display device, and can improve the localization or the quality of sound output in opposite directions in the double-faced display device.

A loudspeaker module for a hearing device has a loudspeaker, which has a loudspeaker diaphragm and a drive for the loudspeaker diaphragm, and a housing, in which the loudspeaker is arranged. Furthermore, the loudspeaker module contains an antenna unit, which has an antenna coil having a coil axis, a tubular coil core, which forms a sound channel, and an antenna base plate, in which a sound passage opening that opens into the sound channel is formed. The antenna coil, the coil core and the antenna base plate in this case prescribe an antenna characteristic of the antenna unit. The side wall of the housing on the diaphragm side is in this case formed by the antenna base plate.

An electromechanical transducer of the invention comprises a structural unit, an armature, and the first and second elastic units. The structural unit includes magnets, a yoke and a coil. The armature includes an inner portion disposed to pass through inside the structural unit and two outer portions protruding from the inner portion in a first direction, and the armature constitutes a magnetic circuit with the structural unit via two regions through which components of the magnetic flux flow in reverse directions in the inner region. The elastic units give restoring forces to the outer portions in response to displacement of the armature due to magnetic forces of the magnetic circuit. In the armature, a cross-sectional area at a predetermined position between the two regions is smaller than that at the two regions, and magnetic flux flowing in the first direction within a range of displacement of the armature.

An acoustic diaphragm made at least in part from an expanded material. The expanded material includes one or more of cellulose, synthetic fibers and glass fibers. The expanded material has more than about 55% by volume voids.

A balanced vibration system including a magnetic circuit unit, a vibration unit and a casing. The magnetic circuit unit and the vibration unit are inside the casing. The vibration unit includes a balanced iron core and a vibrating diaphragm; the balanced iron core is movably connected with the casing, the vibrating diaphragm is fixed on the casing, and the balanced iron core drives the vibrating diaphragm; the magnetic circuit unit includes a magnetic circuit coil and magnet groups, the magnetic circuit coil is sleeved on the balanced iron core, and the two magnet groups are respectively located at ends of the balanced iron core along an axial direction; each magnet group includes magnets which are arranged oppositely at both sides of the balanced iron core; when the magnetic circuit coil is ON, magnetic field forces applied by the two magnet groups to the balanced iron core are same in direction.