The present disclosure relates to dual-diaphragm moving-coil audio transducers for hearing devices. The transducer includes a magnetic circuit including an inner portion located between first and second coils coupled to corresponding diaphragms supported by a housing. An outer portion of the magnetic circuit is adjacent outer portions of the first and second coils. The transducer emits sound when the first diaphragm moves in a first direction and the second diaphragm moves in a second direction, opposite the first direction, in response to an electrical audio signal applied to the first and second coils.

The present disclosure relates to dual-diaphragm moving-coil audio transducers for hearing devices. The transducer includes a magnetic circuit including an inner portion located between first and second coils coupled to corresponding diaphragms supported by a housing. An outer portion of the magnetic circuit is adjacent outer portions of the first and second coils. The transducer emits sound when the first diaphragm moves in a first direction and the second diaphragm moves in a second direction, opposite the first direction, in response to an electrical audio signal applied to the first and second coils.

A testing system includes a testing apparatus and a crack noise monitoring device. The testing apparatus includes a testing stage and an element pickup module for pressing a semiconductor element on the testing stage. The crack noise monitoring device includes a database unit, a sound conduction set, a voiceprint generation unit and a processing unit. The database unit has a first voiceprint pattern. The sound conduction set is connected to the voiceprint generation unit and the testing apparatus for transmitting a sound wave from the semiconductor element to the voiceprint generation unit. The voiceprint generation unit receives and converts the sound wave into a second voiceprint pattern. The processing unit is electrically connected to the voiceprint generating unit and the database unit for determining whether the first voiceprint pattern is identical to the second voiceprint pattern.

A testing system includes a testing apparatus and a crack noise monitoring device. The testing apparatus includes a testing stage and an element pickup module for pressing a semiconductor element on the testing stage. The crack noise monitoring device includes a database unit, a sound conduction set, a voiceprint generation unit and a processing unit. The database unit has a first voiceprint pattern. The sound conduction set is connected to the voiceprint generation unit and the testing apparatus for transmitting a sound wave from the semiconductor element to the voiceprint generation unit. The voiceprint generation unit receives and converts the sound wave into a second voiceprint pattern. The processing unit is electrically connected to the voiceprint generating unit and the database unit for determining whether the first voiceprint pattern is identical to the second voiceprint pattern.

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 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.

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.

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.

A method of forming a device having a compliant member includes creating a membrane having one or more elastomeric layers which are at least partially cured. Another elastomeric layer is provided on the membrane in an uncured state. At least one of a bobbin and a housing are positioned so that an end of the bobbin or housing, or the ends of both the bobbin and housing, extend at least partially into the uncured elastomeric layer. The uncured elastomeric layer is then cured to secure it to the membrane and to the housing or bobbin, or both the housing and bobbin. The method substantially reduces or eliminates the formation of holes that can form during fabrication or use of the device.

A method of forming a device having a compliant member includes creating a membrane having one or more elastomeric layers which are at least partially cured. Another elastomeric layer is provided on the membrane in an uncured state. At least one of a bobbin and a housing are positioned so that an end of the bobbin or housing, or the ends of both the bobbin and housing, extend at least partially into the uncured elastomeric layer. The uncured elastomeric layer is then cured to secure it to the membrane and to the housing or bobbin, or both the housing and bobbin. The method substantially reduces or eliminates the formation of holes that can form during fabrication or use of the device.