A speaker device is provided. The speaker device includes a frame, a vibration unit and a magnetic circuit unit. The vibration unit and the magnetic circuit unit are fixed to the frame. The magnetic circuit unit is configured to drive the vibration unit to vibrate to produce sound. The magnetic circuit unit includes a yoke. The yoke and the frame are spaced to form a leakage port. The vibration unit includes a diaphragm, a voice coil, and an elastic support assembly. The auxiliary diaphragm has one end fixed to the frame and the other end connected to the voice coil. The auxiliary diaphragm is provided with multiple vents spaced and penetrating the auxiliary diaphragm. The present disclosure can increase the circulation of gases above and below the auxiliary diaphragm, so that a side leakage effect of the speaker device is improved, thereby improving acoustic performance of the speaker device.

A diaphragm for a balanced armature receiver and combinations thereof. The diaphragm includes a paddle having an area of concentrated mass located at or near a central portion of the paddle, the area of concentrated mass having an area density greater than an area density of other portions of the paddle, wherein the area of concentrated mass shifts a bending-mode frequency of the paddle to a lower frequency compared to a bending-mode frequency of the paddle in the absence of the area of concentrated mass.

A diaphragm for a balanced armature receiver and combinations thereof. The diaphragm includes a paddle having an area of concentrated mass located at or near a central portion of the paddle, the area of concentrated mass having an area density greater than an area density of other portions of the paddle, wherein the area of concentrated mass shifts a bending-mode frequency of the paddle to a lower frequency compared to a bending-mode frequency of the paddle in the absence of the area of concentrated mass.

There is disclosed herein a high amplitude micro loudspeaker comprising a magnet circuit, comprised by a magnet of a select size and shape mounted to a back plate. A voice coil is of a size and shape to be sleeved about the magnet. A speaker frame is operatively secured to the back plate around a periphery of the magnet to define a space therebetween for receiving the voice coil. Front and rear suspension components are respectively secured to a front and rear of the voice coil and to a front and rear of the speaker frame whereby the voice coil is supported so that it is suspended and sleeved about the magnet. A diaphragm assembly is secured to the front of the speaker frame and the front of the voice coil.

The present disclosure provides speaker device. The speaker device includes frame, vibration unit and magnetic circuit unit, where vibration unit includes diaphragm, voice coil and holder; holder includes holder body and first connecting portion; voice coil includes pair of first sides and pair of second sides; first side is provided with elastic support member fixed to frame and fixed to first connecting portion; elastic support member and first side enclose an accommodating space; magnetic circuit unit includes main magnetic body and an auxiliary magnetic body; auxiliary magnetic body includes first magnetic portion that is respectively spaced apart from first side and located in accommodating space; elastic support member include an auxiliary diaphragm; auxiliary diaphragm is provided with an avoiding groove. The present disclosure can increase volume of magnetic circuit unit to increase BL value, and can effectively reduce weight of vibration unit to improve sensitivity.

The present disclosure provides speaker device. The speaker device includes frame, vibration unit and magnetic circuit unit, where vibration unit includes diaphragm, voice coil and holder; holder includes holder body and first connecting portion; voice coil includes pair of first sides and pair of second sides; first side is provided with elastic support member fixed to frame and fixed to first connecting portion; elastic support member and first side enclose an accommodating space; magnetic circuit unit includes main magnetic body and an auxiliary magnetic body; auxiliary magnetic body includes first magnetic portion that is respectively spaced apart from first side and located in accommodating space; elastic support member include an auxiliary diaphragm; auxiliary diaphragm is provided with an avoiding groove. The present disclosure can increase volume of magnetic circuit unit to increase BL value, and can effectively reduce weight of vibration unit to improve sensitivity.

Embodiments of this application disclose an electroacoustic transducer, including a center magnet, two first side magnets, two second side magnets, a voice coil, a voice diaphragm, and two flexible printed circuit boards. The two first side magnets are symmetrically arranged on two sides of the center magnet, and a first gap is formed between the first side magnet and the center magnet. One end of the voice coil is partially located in the first gap, and the voice diaphragm is fixedly connected to the other end of the voice coil. The two flexible printed circuit boards are symmetrically arranged on two sides of the center magnet. The electroacoustic transducer has comparatively high magnetic induction strength and comparatively high sensitivity.

One of the main objects of the present invention is to provide a MEMS speaker with improved high frequency acoustic performance. To achieve the above-mentioned object, the present invention provides a MEMS speaker including a base with a first cavity and two openings opposite to each other; a substrate covering one of the openings; a diaphragm fixed to the base and covers the other opening; and a MEMS driver. The MEMS driver includes a first support part forming a distance from the diaphragm, a second support part extending from an edge of the first support part toward the diaphragm for supporting the diaphragm, and a piezoelectric member attached to the first support part.

A passive radiator unit and a speaker system using the passive radiator unit are provided. The passive radiator unit includes a first passive radiator comprising a first moving mass; a second passive radiator oriented opposite to the first passive radiator, the second passive radiator comprising a second moving mass; and a connecting structure connected between the first moving mass of the first passive radiator and the second moving mass of the second passive radiator. The connecting structure is configured to have a greater radial stiffness than an axial stiffness thereof to thereby prevent rocking movements while allowing normal vibrations of the first passive radiator and the second passive radiator in an axial direction of the passive radiator unit.

A passive radiator unit and a speaker system using the passive radiator unit are provided. The passive radiator unit includes a first passive radiator comprising a first moving mass; a second passive radiator oriented opposite to the first passive radiator, the second passive radiator comprising a second moving mass; and a connecting structure connected between the first moving mass of the first passive radiator and the second moving mass of the second passive radiator. The connecting structure is configured to have a greater radial stiffness than an axial stiffness thereof to thereby prevent rocking movements while allowing normal vibrations of the first passive radiator and the second passive radiator in an axial direction of the passive radiator unit.