The present disclosure relates to the technical field of an electronic device, particularly to transducers, loudspeakers, and acoustic output devices.
Loudspeakers are widely used in daily life. Existing loudspeakers often suffer from issues such as low sensitivity, heavy weight, magnetically biased transducers, and weak magnetic field strength. The present disclosure provides transducers, loudspeakers, and acoustic output devices that address the aforementioned problems.
One of the embodiments of the present disclosure provides a transducer, comprising: a magnetic circuit system, the magnetic circuit system including a magnet assembly and a magnetically conductive cover, the magnetically conductive cover at least partially surrounding the magnet assembly; a vibration plate, the vibration plate including a first vibration plate and a second vibration plate, the first vibration plate and the second vibration plate are respectively disposed on two sides of the magnet assembly along a vibration direction of the transducer, and the first vibration plate and the second vibration plate are configured to elastically support the magnet assembly; and a coil disposed in the magnetic circuit system, the coil is within a magnetic field range of the magnet assembly, and an overall direct current (DC) impedance of the coil is in a range of 6Ω-10Ω.
One of the embodiments of the present disclosure provides a transducer comprising: a magnetic circuit system, the magnetic circuit system including a magnet assembly and a magnetically conductive cover, the magnetically conductive cover at least partially surrounding the magnet assembly; a vibration plate, the vibration plate including a first vibration plate and a second vibration plate, the first vibration plate and the second vibration plate are respectively disposed on two sides of the magnet assembly along a vibration direction of the transducer, and the first vibration plate and the second vibration plate are configured to elastically support the magnet assembly, a resonance peak frequency of the transducer is less than 300 Hz.
One of the embodiments of the present disclosure provides a transducer comprising: a magnetic circuit system, the magnetic circuit system including a magnet assembly and a magnetically conductive cover, the magnetically conductive cover at least partially surrounding the magnet assembly; a vibration plate, the vibration plate including a first vibration plate and a second vibration plate, the first vibration plate and the second vibration plate are respectively disposed on two sides of the magnet assembly along a vibration direction of the transducer, and the first vibration plate and the second vibration plate are configured to elastically support the magnet assembly, an equivalent stiffness of the first vibration plate and/or the second vibration plate in any direction within a plane perpendicular to the vibration direction of the magnet assembly is greater than 4.7×104 N/m.
One of the embodiments of the present disclosure provides a transducer comprising: a magnetic circuit system, the magnetic circuit system including a magnet assembly and a magnetically conductive cover, the magnetically conductive cover at least partially surrounding the magnet assembly; a vibration plate, the vibration plate including a first vibration plate and a second vibration plate, the first vibration plate and the second vibration plate are respectively disposed on two sides of the magnet assembly along a vibration direction of the transducer, and the first vibration plate and the second vibration plate are configured to elastically support the magnet, the magnet is provided with a first hole, and each of the magnetically conductive plates is provided with a second hole corresponding to the first hole.
One of the embodiments of the present disclosure provides a transducer comprising: a magnetic circuit system, the magnetic circuit system including a magnet assembly and a magnetically conductive cover, the magnetically conductive cover at least partially surrounding the magnet assembly; a vibration plate, the vibration plate including a first vibration plate and a second vibration plate, the first vibration plate and the second vibration plate are respectively disposed on two sides of the magnet assembly along a vibration direction of the transducer, and the first vibration plate and the second vibration plate are configured to elastically support the magnet, a ratio of a thickness of each magnetically conductive plate to a thickness of the magnet is in a range of 0.05-0.35.
One of the embodiments of the present disclosure provides a transducer comprising: a magnetic circuit system, the magnetic circuit system including a magnet assembly and a magnetically conductive cover, the magnetically conductive cover at least partially surrounding the magnet assembly; a vibration plate, the vibration plate including a first vibration plate and a second vibration plate, the first vibration plate and the second vibration plate are respectively disposed on two sides of the magnet assembly along a vibration direction of the transducer, and the first vibration plate and the second vibration plate are configured to elastically support the magnet, at least one of the magnet, a magnetically conductive plate of the magnetically conductive plates, and the magnetically conductive cover includes multiple magnetic parts with different magnetization directions.
One of the embodiments of the present disclosure provides a loudspeaker comprising a housing, an electronic component, and a transducer according to any embodiment described in the present disclosure, the housing forms a cavity that accommodates the transducer and the electronic component.
One of the embodiments of the present disclosure provides an acoustic output device comprising a fixing assembly and a loudspeaker according to any embodiment described in the present disclosure, the fixing assembly being connected to the loudspeaker.
The technical schemes of embodiments of the present disclosure will be more clearly described below, and the accompanying drawings need to be configured in the description of the embodiments will be briefly described below. Obviously, the drawings in the following description are merely some examples or embodiments of the present disclosure, and will be applied to other similar scenarios according to these accompanying drawings without paying creative labor. Unless obviously obtained from the context or the context illustrates otherwise, the same numeral in the drawings refers to the same structure or operation.
It should be understood that the “system,” “device,” “unit,” and/or “module” used herein is a method for distinguishing different components, elements, components, parts or assemblies of different levels. However, if other words may achieve the same purpose, the words may be replaced by other expressions.
As shown in the present disclosure and claims, unless the context clearly prompts the exception, “a,” “one,” and/or “the” is not specifically singular, and the plural may be included. It will be further understood that the terms “comprise,” “comprises,” and/or “comprising,” “include,” “includes,” and/or “including,” when used in present disclosure, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
The embodiments in the present disclosure describe an acoustic output device 100. In some embodiments, the acoustic output device 100 may include a loudspeaker 10 and a fixing assembly 20, the loudspeaker 10 is connected to the fixing assembly 20. The fixing assembly 20 may be configured to support the loudspeaker 10 to be worn at a wearing position. In some embodiments, the wearing position may be a specific position on a user's head. For example, the wearing position may include the ear, mastoid, temporal bone, parietal bone, frontal bone, etc. As another example, the wearing position may include positions on both left and right sides of the head and located on a front side of the user's ears on a sagittal axis of the human body. In some embodiments, the loudspeaker 10 may include a transducer that may be configured to convert electrical signals (containing sound information) into mechanical vibrations, allowing the user to hear sound through the acoustic output device 100. Specifically, the mechanical vibrations generated by the loudspeaker 10 may be mainly transmitted via media such as the user's skull (i.e., bone conduction) to form a bone-conducted sound, or mainly via media such as air (i.e., air conduction) to form an air-conducted sound, or may adopt a combination of the bone conduction and the air conduction to transmit sound. For more information about the loudspeaker 10, please refer to
In some embodiments, the fixing assembly 20 may be arranged in a ring shape, wrapping around the user's head through their forehead and back of the head. In some embodiments, the fixing assembly 20 may be a curved rear-mounted structure adapted to the back of the user's head. In some embodiments, the fixing assembly 20 may be an ear-hook structure with a curved portion adapted to hang over the user's ear auricle. In some embodiments, the fixing assembly 20 may be a spectacle frame structure with nose pads and side temples that may be worn on the user's face and ears. For more embodiments of the fixing assembly 20, please refer to
In some embodiments, the acoustic output device 100 may include at least two loudspeakers 10. All of the at least two loudspeakers 10 may convert electrical signals into mechanical vibrations, enabling the acoustic output device 100 to achieve stereo sound effects. For example, the acoustic output device 100 may include two loudspeakers 10. The two loudspeakers 10 may be placed on the user's left and right ear sides, respectively. In some application scenarios where stereo sound is not particularly critical (such as hearing aids for hearing-impaired patients, teleprompter use for live broadcasting, etc.), the acoustic output device 100 may also include only one loudspeaker 10.
When the acoustic output device 100 includes two loudspeakers 10, by way of an example only, the fixing assembly 20 may include two ear hook assemblies and a rear-mounted assembly. Two ends of the rear-mounted assembly are respectively connected to one end of a corresponding ear hook assembly. The other end of each ear hook assembly which is opposite the rear-mounted assembly is respectively connected to a corresponding loudspeaker 10. Specifically, the rear-mounted assembly may be curved to wrap around the back of the user's head, and the ear hook components may also be curved to hang between the user's ears and head, facilitating the wearing requirements of the acoustic output device 100. Thus, when the acoustic output device 100 is in a wearing state, the two loudspeakers 10 are located on the left and right sides of the user's head, respectively. The two loudspeakers 10, with the cooperation of the fixing assembly 20, press against the user's head, allowing the user to hear the sound output by the acoustic output device 100.
In some embodiments, the loudspeaker 10 described in the present disclosure may be a bone conduction loudspeaker and/or an air-conduction loudspeaker. In some embodiments, the acoustic output device 100 may be an electronic device with an audio functionality. For example, the acoustic output device 100 may be an electronic device such as music headphones, hearing aid headphones, bone conduction headphones, hearing aids, audio glasses, a smart helmet, a VR device, an AR device, etc.
In some embodiments, the loudspeaker 10 may further include a damping plate 14. The transducer 12 may be suspended within the accommodating cavity of the housing 11 via the damping plate 14. The vibration panel 13 may not contact with the housing 11. In this case, due to the presence of the damping plate 14, the mechanical vibrations generated by the transducer 12 may be less or even not transmitted to the housing 11, thereby avoiding, to some extent, the vibrations of the air outside the loudspeaker 10 caused by the housing 11. This helps reduce sound leakage from the loudspeaker 10. In some embodiments, the housing 11 may have an open end, and the vibration panel 13 is disposed outside the housing 11 and opposes the open end. In other words, an edge of the vibration panel 13 is disconnected from the open end of the housing 11. A connecting rod 131 is provided between the vibration panel 13 and the transducer 12. One end of the connecting rod 131 is connected to the transducer 12, and the other end passes through the open end of the housing 11 to connect to the vibration panel 13, so that the vibration panel 13 and the transducer 12 do not come into contact with the housing 11, thereby reducing sound leakage from the loudspeaker 10. In some embodiments, the damping plate 14 may be connected between the connecting rod 131 and the housing 11 to achieve suspensions of the vibration panel 13 and the transducer 12. In some embodiments, at least one through-hole (also known as a “sound leakage reduction hole”) may be provided on the housing 11 to connect the accommodating cavity of the housing 11 with the outside of the loudspeaker 10, thereby reducing sound leakage from the loudspeaker 10.
In some embodiments, the loudspeaker 10 may also include a face pad (not shown in the figure) connected to the vibration panel 13. The face pad is configured to contact with the user's skin, meaning the vibration panel 13 may contact with the user's skin through the face pad. A Shore hardness of the face pad may be less than a Shore hardness of the vibration panel 13, which indicates that the face pad may be softer than the vibration panel 13. For example, the material of the face pad may be a soft material such as silicone, while the material of the vibration panel 13 may be a hard material such as polycarbonate or glass fiber reinforced plastic. This may improve the wearing comfort of the loudspeaker 10, make the loudspeaker 10 fit closely to the user's skin, and further enhance the sound quality of the loudspeaker 10. In some embodiments, the face pad may be detachably connected to the vibration panel 13 for easy replacement by the user. For instance, the face pad may be fitted over the vibration panel 13.
Referring to
In some embodiments, the magnetic circuit system 123 may include a magnet assembly 1231 and a magnetic conductive cover 1232. The magnetic conductive cover 1232 may be fitted over the coil 124, and the magnet assembly 1231 may be disposed inside the coil 124. The magnetic conductive cover 1232 and the magnet assembly 1231 are spaced apart in a direction perpendicular to the vibration direction, thereby forming the aforementioned magnetic gap between an inner wall of the magnetic conductive cover 1232 and an outer side of the magnet assembly 1231. In some embodiments, the coil 124 may be wounded around the outside of the magnet assembly 1231 along an axis parallel to the vibration direction of the transducer 12. In some embodiments, the magnetic conductive cover 1232 of the magnetic circuit system 123 encircles an axis parallel to the vibration direction of the transducer 12 outside the coil 124, meaning the magnetic conductive cover 1232 and the magnet assembly 1231 are spaced apart in a direction perpendicular to the vibration direction of the transducer 12. Specifically, the coil 124 may be connected to the magnetic conductive cover 1232. In some embodiments of the present disclosure, the coil 124 is attached to the inner wall of the magnetic conductive cover 1232. In some embodiments, the diaphragm 122 may be connected between the magnetic conductive cover 1232 and the magnet assembly 1231. The diaphragm 122 may be served as an elastic support for the magnet assembly 1231. For example, the vibration plate 122 and the magnetic circuit system 123 may be arranged in the vibration direction, and a side of the vibration plate 122 perpendicular to the vibration direction may be connected to an end perpendicular to the vibration direction of the magnetic conductive cover 1232, thereby achieving the fixation of the magnetic circuit system 123. It should be understood that in other embodiments of the present disclosure, a periphery of the vibration plate 122 may also be connected to the inner wall of the magnetic conductive cover 1232 or other positions, thereby achieving the fixation of the magnetic circuit system 123 relative to the magnetic conductive cover 1232.
In some embodiments, the coil 124 may include a first coil 1241 and a second coil 1242. In some embodiments, the first coil 1241 may extend into the magnetic gap of the magnetic circuit system 123 from a side closer to the vibration panel 13 in the vibration direction, and the second coil 1242 may extend into the magnetic gap of the magnetic circuit system 123 from a side farther from the vibration panel 13 in the vibration direction. In some embodiments, to simplify the assembly process, the first coil 1241 and the second coil 1242 may be inserted together into the magnetic gap of the magnetic circuit system 123 from the side closer to the vibration panel 13. In some embodiments, the transducer 12 may further include a retaining portion for maintaining the shape of the first coil 1241 and the second coil 1242. For example, the first coil 1241 and the second coil 1242 may be integrated into a single structure. Specifically, the first coil 1241 and the second coil 1242 may be wound around a shaping material, and then the retaining portion (such as high-temperature tape or other retaining materials) may be adhered to the exterior of the first coil 1241 and the second coil 1242, forming an integrated structure. The first coil 1241 and the second coil 1242, fixed on the retaining portion, extend into the magnetic gap of the magnetic circuit system 123 from the same side of the vibration panel 13, thereby simplifying the assembly process of the coil 124. In some embodiments, the two coils are wound from the same metal wire, or one segment of the two coils is connected, so that there are only two lead wires for the inlet and outlet of the two coils, facilitating wiring and subsequent electrical connections with other structures.
In some embodiments, the vibration plate 122 may include a first vibration plate 125 and a second vibration plate 126. Along the vibration direction of the transducer 12, the first vibration plate 125 and the second vibration plate 126 may elastically support the magnet assembly 1231 from opposite sides of the magnet assembly 1231. Therefore, in the embodiments described in the present disclosure, the magnet assembly 1231 is elastically supported on opposite sides in the vibration direction of the transducer 12, making it free from significant shaking or other abnormal vibrations, thus improving the stability of the vibrations of the transducer 12.
As an example, as shown in
In some embodiments, the magnet assembly 1231 may include a magnet 1233 and a magnetically conductive plate. In some embodiments, the magnet 1233 and the magnetically conductive plate are arranged along the vibration direction of the transducer 12. In some embodiments, the magnetically conductive plate may be located on one or both sides of the magnet 1233 in the vibration direction of the transducer 12. In some embodiments, the magnetically conductive plate may include a first magnetically conductive plate 1234 and a second magnetically conductive plate 1235 located on opposite sides of the magnet 1233 in the vibration direction of the transducer 12. The first vibration plate 125 may support the magnet assembly 1231 from a side of the first magnetically conductive plate 1234 facing away from the second magnetically conductive plate 1235, and the second vibration plate 126 may support the magnet assembly 1231 from a side of the second magnetically conductive plate 1235 facing away from the first magnetically conductive plate 1234. For example, a central region 1252 of the first vibration plate 125 is connected to the side of the first magnetically conductive plate 1234 facing away from the second magnetically conductive plate 1235, and a central region 1262 of the second vibration plate 126 is connected to the side of the second magnetically conductive plate 1235 facing away from the first magnetically conductive plate 1234. In some embodiments, the corners of the magnetically conductive plates (e.g., the first magnetically conductive plate 1234 and/or the second magnetically conductive plate 1235) far from the magnet 1233 may be chamfered. For example, the corners on the opposite sides of the first magnetically conductive plate 1234 and the second magnetically conductive plate 1235 (i.e., the corners far from the magnet 1233) may be chamfered to adjust the distribution of the magnetic field formed by the magnetic circuit system 123, making the magnetic field concentrated. In some embodiments, in the vibration direction of the transducer 12, a half-height of the first coil 1241 may be equal to a half-thickness of an edge line parallel to the vibration direction of the first magnetically conductive plate 1234, and a half-height of the second coil 1242 may be equal to the half-thickness of the edge line parallel to the vibration direction of the second magnetically conductive plate 1235, allowing the magnetic field to be concentrated in the rectangular portions of the first magnetically conductive plate 1234 and/or the second magnetically conductive plate 1235 other than the chamfered portions.
In some embodiments, the magnetic conductive cover 1232 may be connected to the bracket 121, and the bracket 121 may be connected to the housing 11 via the damping plate 14, thereby suspending the transducer 12 in the accommodation chamber of the housing 11. At this time, as shown in
In some embodiments, if the stiffness of the damping plate 14 is too small, it is difficult for the magnetic circuit system 123 to be stably suspended within the housing 11 by the damping sheet 14, which easily leads to poor stability during the vibration of the transducer 12. Conversely, if the stiffness of the damping sheet 14 is too large, the vibration of the transducer 12 is prone to be transmitted to the housing 11 via the damping sheet 14, resulting in excessive sound leakage of the loudspeaker 10. In some embodiments, in order to achieve good stability during the vibration of the transducer 12 and reduce the sound leakage of the loudspeaker 10, a ratio between the stiffness of the damping sheet 14 and the stiffness of the first vibration plate 125 (or the second vibration plate 126) may be within a range of 0.1 to 5.
In some embodiments, the loudspeaker 10 may also include an electronic component. The electronic component is disposed within the accommodation cavity of the housing 11 or attached to the outer side of the housing 11. In some embodiments, the electronic component may include a vibration-sensitive component and a non-vibration-sensitive component. The vibration-sensitive component may include an air-conduction loudspeaker, an acceleration sensor, etc. The non-vibration-sensitive component may include a battery, a circuit board, etc. The battery may be configured to power the loudspeaker 10 to enable the loudspeaker 10 to operate. The circuit board may be integrated with a signal processing circuit, which is configured for signal processing of electrical signals. In some embodiments, the signal processing may include a frequency modulation processing, an amplitude modulation processing, a filtering processing, a noise reduction processing, etc. The air-conduction loudspeaker may be configured to convert electrical signals into vibration signals (sound waves), which are transmitted to the auditory nerve through the air and perceived by the user. The acceleration sensor may be configured to measure the vibration acceleration of the vibration panel 13. More information about the air-conduction loudspeaker and the acceleration sensor can be found below, for example, by referring to the descriptions of
In the various embodiments shown in
In some embodiments, the diaphragm 15 of the air-conduction loudspeaker is connected between the magnet assembly 1231 and the housing 11 of the transducer 12, and a vibration direction of the diaphragm 15 is parallel to the vibration direction of the transducer 12. Referring to
In some embodiments, to prevent the air-conduction loudspeaker from resonating and producing leakage peaks due to the vibration of the transducer 12, an air-conduction vibration direction of the air-conduction loudspeaker may be different from the vibration direction of the transducer 12 (i.e., the bone-conduction vibration direction) to prevent mutual interference in the same direction.
In some embodiments, to prevent the acceleration sensor from being affected by the vibration of the transducer 12 when measuring the acceleration of the vibrating panel 13, the vibration direction of the transducer 12 may be approximately perpendicular to the vibration-sensitive end of the acceleration sensor.
It should be noted that when the electronic component is a vibration-sensitive component such as an air-conduction loudspeaker or an acceleration sensor, the vibration direction of the vibration-sensitive component should be approximately perpendicular to the vibration direction of the transducer 12 to avoid the vibration-sensitive component being affected by the vibration of the transducer. The phrase “the vibration direction of the vibration-sensitive component is approximately perpendicular to the vibration direction of the transducer 12” mentioned in the present disclosure refers to that when the vibration-sensitive component is an air-conducted loudspeaker, the vibration direction of the transducer 12 is approximately perpendicular to the vibration direction of the diaphragm of the air-conduction loudspeaker; and when the vibration-sensitive component is an acceleration sensor, the vibration direction of the transducer 12 is approximately perpendicular to the vibration-sensitive end of the acceleration sensor. When the electronic component is a non-vibration-sensitive component such as a battery or a circuit board, the battery or circuit board may be placed at any position within the housing 11 to achieve an integrated design of the acoustic output device 100.
It can be understood that in some embodiments, the electronic component may include both the vibration-sensitive component and the non-vibration-sensitive component, and the vibration-sensitive component may be made approximately perpendicular to the vibration direction of the transducer 12. For example, in some embodiments, the electronic component include a vibration-sensitive acceleration sensor and a non-vibration-sensitive circuit board. The acceleration sensor is mounted on the circuit board and housed within the housing of the loudspeaker 10 to achieve the integration of the acoustic output device. In this case, the acceleration sensor may be made approximately perpendicular to the vibration direction of the transducer 12.
In some embodiments, to facilitate the assembly of lead wires of the coil 124, making the inlet and outlet of the coil 124 at the same position of the magnetic conductive cover 1232, a count of coil windings along the radial direction of the transducer 12 may be even. For example, a count of radial coil windings may be 2, 4, 6, 8, etc. As shown in
In some embodiments, the coil 124 may include a first coil 1241 and a second coil 1242. In some embodiments, the first coil 1241 and the second coil 1242 may be arranged along the vibration direction of the transducer 12. The first coil 1241 and the second coil 1242 are connected in series or in parallel. For the first coil 1241 and the second coil 1242 connected in series or in parallel, an inlet position and an outlet position of each coil are both located at a same position of the magnetic conductive cover 1232, facilitating the assembly of the lead wires of the first coil 1241 and the second coil 1242. The inlet and outlet positions of the first coil 1241 may both be located at the same position of the magnetic conductive cover 1232, and the inlet and outlet positions of the second coil 1242 may both be located at the same position of the magnetic conductive cover 1232. For example, the inlet position of the first coil 1241, the outlet position of the first coil 1241, the inlet position of the second coil 1242, and the outlet position of the second coil 1242 may all be located at a middle position of the magnetic conductive cover 1232 (e.g., along the direction perpendicular to the vibration direction of the transducer 12, the middle of the magnetic conductive cover 1232). In some embodiments, winding directions of the first coil 1241 and the second coil 1242 may be opposite or directions of currents in the first coil 1241 and the second coil 1242 may be opposite. Under the drive of the dual coils (i.e., the coil 124 includes the first coil 1241 and the second coil 1242), the transducer 12 vibrates relatively, which may increase a vibration amplitude of the transducer 12 compared to a single voice coil. In some embodiments, the use of a dual-coil structure may achieve a lower high-frequency impedance.
In some embodiments, excessively low impedance results in an increase in current under a same battery voltage, which not only consumes more power but also reduces battery life under the same battery capacity. On the other hand, if the battery cannot output the increased current, clipping distortion will occur. Conversely, excessively high impedance causes a decrease in current under the same battery voltage, resulting in lower sensitivity and a reduction in volume. Therefore, to balance battery life, distortion, sensitivity, and volume, the overall DC impedance of the coil 124 may be within a range of 6Ω-10Ω. In some embodiments, for the first coil 1241 and the second coil 1242 in the transducer 12, the design may be based on the following requirements:
Firstly, to ensure that the overall DC impedance of the coil 124 (consisting of the first coil 1241 and the second coil 1242) falls within a range of 6Ω-10Ω, a DC impedance range of a single coil (the first coil 1241 or the second coil 1242) may vary depending on a connection method (series or parallel). For example, to achieve an overall DC impedance of 8Ω for the coil 124, when the two coils are connected in series, the DC impedance of each individual coil (the first coil 1241 or the second coil 1242) should be 4Ω, and when the two coils are connected in parallel, the DC impedance of each individual coil should be 16Ω.
Secondly, to minimize an overall weight of the loudspeaker 10, a volume of the magnetic conductive cover 1232 and further a mass of the magnetic conductive cover 1232 may be reduced by making the inner wall of the magnetic conductive cover 1232 adhere to the outer wall of the coil 124 (including the first coil 1241 and the second coil 1242). While ensuring that the spacing between the first coil 1241 and the second coil 1242 along the vibration direction of the transducer 12 is within a range of 1.5 mm-2 mm, a shape of the coil 124 (the first coil 1241 and the second coil 1242) may be “slender” by increasing an axial height and reducing a radial width of the coil 124. This results in a corresponding reduction in an inner diameter of the magnetic conductive cover 1232, and subsequently, a reduction in the outer diameter while maintaining the thickness of the magnetic conductive cover 1232, which in turn reduces the mass of the magnetic guide cover 1232 and the overall weight of the loudspeaker 10. In some embodiments, the shape of the coil 124 (including the first coil 1241 and the second coil 1242) may be “slender” by designing parameters such as a wire diameter, radial coil windings, and axial layers of the coil 124 to meet these requirements. In some embodiments, to achieve a “slender” shape for the coil 124 (the first coil 1241 and the second coil 1242), a ratio of the axial height to the radial width of the first coil or the second coil may be no less than 3. For example, the ratio of the axial height to the radial width of the first coil or the second coil may be no less than 3.5.
Thirdly, since the axial height of the transducer 12 is primarily determined by the size of the internal magnet assembly 1231, to meet the size requirements of the transducer 12 (for example, when the acoustic output device 100 is a headset, to ensure that the height of the loudspeaker 10 in the headset is within a range of less than 5.7 mm), the axial height of a single coil (the first coil 1241 and/or the second coil 1242) may be within a range of less than 2.85 mm. For example, the axial height of a single coil (the first coil 1241 and/or the second coil 1242) may be around 2 mm.
To meet the above requirements, in some embodiments, the first coil 1241 and the second coil 1242 may be connected in series. To ensure that the overall DC impedance of the coil 124 falls within a range of 6Ω-10Ω, the DC impedance of the first coil 1241 and/or the second coil 1242 may be within a range of 4 Ω±1Ω. For example, to achieve the overall DC impedance of the coil 124 within a range of 7Ω-9Ω, the DC impedance of the first coil 1241 and/or the second coil 1242 may be within a range of 3.5Ω-4.5Ω. As another example, to achieve the overall DC impedance of the coil 124 within a range of 8 Ω±0.8Ω, the DC impedance of the first coil 1241 and/or the second coil 1242 may be within a range of 4 Ω±0.4Ω. In some embodiments, the wire diameter of the first coil 1241 and/or the second coil 1242 may be within a range of 0.11 mm-0.13 mm.
To meet the above requirements, in some embodiments, the first coil 1241 and/or the second coil 1242 may satisfy one of the following characteristics: a wire diameter of 0.11 mm, 2 to 6 radial coil windings, and 8 to 20 axial layers; a wire diameter of 0.12 mm, 2 to 6 radial coil windings, and 9 to 20 axial layers; or a wire diameter of 0.13 mm, 2 to 6 radial coil windings, and 10 to 22 axial layers. For example, the wire diameter of the first coil 1241 and/or the second coil 1242 may be 0.11 mm, with 3 to 5 radial coil windings and 12 to 20 axial layers. As another example, the wire diameter may be 0.12 mm, with 3 to 5 radial coil windings and 14 to 20 axial layers. As a further example, the wire diameter may be 0.13 mm, with 3 to 4 radial coil windings and 15 to 22 axial layers.
In some embodiments, the relationship between the wire diameter, the radial coil windings, the axial layers, and the DC resistance of the single coils connected in series (the first coil 1241 and/or the second coil 1242) is shown in Table 1.
According to Table 1, to keep the DC resistance of a single coil (the first coil 1241 or the second coil 1242) within a range of 4 Ω±1 Ω while maintaining an even count of radial coil windings, the exemplary wire diameter of the first coil 1241 and/or the second coil 1242 may be 0.11 mm, with 4 radial coil windings and 12 axial layers. Under this condition, the DC resistance of the first coil 1241 and/or the second coil 1242 is 4Ω. As another example, the wire diameter may be 0.12 mm, with 4 radial coil windings and 14 axial layers. In this case, the DC resistance of the first coil 1241 and/or the second coil 1242 is 3.93Ω. As a further example, the wire diameter may be 0.12 mm, with 4 radial coil windings and 15 axial layers. The DC resistance of the first coil 1241 and/or the second coil 1242 is 4Ω. Lastly, the wire diameter may be 0.13 mm, with 4 radial coil windings and 18 axial layers. In this scenario, the DC resistance of the first coil 1241 and/or the second coil 1242 is 4.08Ω.
In some embodiments, the first coil 1241 and the second coil 1242 may be connected in parallel. To ensure that the overall DC resistance of the coil 124 falls within a range of 6Ω-10Ω, the DC resistance of the first coil 1241 and/or the second coil 1242 should be within a range of 12Ω-20 Ω individually. For example, to meet the requirement of the overall DC resistance of the coil 124 within a range of 8 Ω±0.8Ω, the DC resistance of the first coil 1241 and/or the second coil 1242 may be within a range of 16 Ω±1.6Ω. In some embodiments, the wire diameter in the first coil 1241 and the second coil 1242 may be in a range of 0.07 mm to 0.08 mm.
To meet the above requirements, in some embodiments, the radial coil windings of the first coil 1241 and/or the second coil 1242 may be 4 to 8 turns, and the axial layers may be 16 to 22 layers. For example, the radial coil windings of the first coil 1241 and/or the second coil 1242 may be 4 to 6 turns, and the axial layers may be 17 to 20 layers.
In some embodiments, to keep the DC resistance of a single coil (the first coil 1241 or the second coil 1242) within a range of 16 Ω±1.6 Ω while maintaining an even count of radial coil windings, Table 2 shows the wire diameter, the radial coil windings, the axial layers, and the DC resistance of exemplary parallel-connected single coils (the first coil 1241 and/or the second coil 1242). For example, the wire diameter of the parallel-connected single coils (the first coil 1241 and/or the second coil 1242) may be 0.08 mm, with 6 radial coil windings and 17 axial layers, corresponding to a DC resistance of 16.16Ω. As another example, the wire diameter may be 0.07 mm, with 4 radial coil windings and 20 axial layers, resulting in a DC resistance of 16.27Ω.
In some embodiments, as shown in
In some embodiments, to avoid reducing the magnetic field strength due to magnetic saturation of the magnetic conductor cover 1232, the thickness of the magnetic conductor cover 1232 in the radial direction of the transducer 12 cannot be too thin. In some embodiments, the thickness of the magnetic conductor cover 1232 in the radial direction of the transducer 12 may be no less than 0.3 mm. However, an excessively thick magnetic conductor cover 1232 may increase the thickness of the transducer 12, so the thickness of the magnetic conductor cover 1232 cannot be too thick. Therefore, considering both weight reduction and avoidance of magnetic saturation, the thickness of the magnetic conductor cover 1232 in the radial direction of the transducer may be within a range of 0.3 mm to 1 mm. For example, the thickness of the magnetic conductor cover 1232 may be within a range of 0.4 mm to 0.9 mm. As another example, the thickness of the magnetic conductor cover 1232 may be within a range of 0.5 mm to 0.8 mm. In some embodiments, as shown in
In some embodiments, an outer diameter shape of the magnetic conductor cover 1232 may be rectangular, elliptical, circular, racetrack-shaped, polygonal, etc. For example, as shown in
In some embodiments, the magnet assembly 1231 may include a magnet 1233 and a magnetic conductor plate disposed on one side of the magnet 1233 in the vibration direction of the transducer 12. When the magnetic conductor plate is too thin, it is prone to magnetic saturation, and the magnetic field strength at the coil position decreases accordingly. However, when the magnetic conductor plate is too thick, due to the limitation of the overall volume of the magnet assembly 1231, if the magnetic conductor plate is too thick, it may easily lead to the magnet 1233 being too thin, resulting in a low magnetic field strength. Therefore, to increase the magnetic field strength and avoid magnetic saturation, a ratio of the thickness of the magnetic conductor plate to the thickness of the magnet 1233 may be within a range of 0.05 to 0.35. For example, the ratio of the thickness of the magnetic conductor plate to the thickness of the magnet 1233 may be within a range of 0.15 to 0.3. In some embodiments, the magnetic conductor plate may include a first magnetic conductor plate 1234 and a second magnetic conductor plate 1235. The first magnetic conductor plate 1234 is located on one side of the magnet 1233 in the vibration direction of the transducer 12, and the second magnetic conductor plate 1235 is located on the other side of the magnet 1233 in the vibration direction of the transducer 12. The ratio of the thickness of the first magnetic conductor plate 1234 or the second magnetic conductor plate 1235 (hereinafter referred to as the magnetic conductor plate) to the thickness of the magnet 1233 is within a range of 0.05 to 0.35. In some embodiments, to increase the magnetic field strength and avoid magnetic saturation, the thickness of the magnetic conductor plate (the first magnetic conductor plate 1234 or the second magnetic conductor plate 1235) may be within a range of 0.5 mm to 1 mm. For example, the thickness of the magnetic conductor plate (the first magnetic conductor plate 1234 or the second magnetic conductor plate 1235) may be within a range of 0.6 mm to 0.7 mm.
In some embodiments, to facilitate the assembly and positioning of the magnet 1233 with the magnetic conductive plate (the first magnetic conductive plate 1234 and/or the second magnetic conductive plate 1235), and to reduce the mass of the transducer 12 (further reducing the overall mass of the acoustic output device 100), holes may be drilled on the magnet 1233 and/or the magnetic conductive plate (the first magnetic conductive plate 1234 and/or the second magnetic conductive plate 1235). For example, as shown in
In some embodiments, to improve the accuracy of assembly, a count of second holes 1234a on the magnetic conductive plate may be at least two. Correspondingly, a count of first holes 1233a on the magnet 1233 may also be at least two, each corresponding to a second hole 1234a.
In
In some embodiments, the position of the second hole 1234a on the magnetic conductor plate has a significant impact on the BL value of the transducer 12. Taking the example of two second holes 1234a placed on the midline of the magnetic conductor plate along its length,
In some embodiments, by setting a count of coils 124 along the radial direction of the transducer 12 as an even number, the inlet position and outlet position of the first coil 1241 or the second coil 1242 are located at the same position of the magnetic conductive cover 1232, enabling the inner wall of the magnetic conductive cover 1232 to fit tightly with the outer wall of the coil 124, thus reducing the mass of the transducer 12 (and subsequently reducing the mass of the loudspeaker 10). Furthermore, by shaping the coil 124 (the first coil 1241 and the second coil 1242) into an “elongated” form and selecting appropriate parameters for the coil 124, the inner diameter of the magnetic conductive cover 1232 may be reduced to reduce the mass of the transducer 12 (and subsequently reducing the mass of the loudspeaker 10). In some embodiments, the mass of the transducer 12 (and subsequently reducing the mass of the loudspeaker 10) may be reduced by setting a weight-reducing slot on the magnetic conductive cover 1232 or by drilling a hole in the magnet 1233 and/or the magnetic conductive plate (the first magnetic conductive plate 1234 and/or the second magnetic conductive plate 1235). In some embodiments, the mass m of the loudspeaker 10 after weight reduction may be within a range of 2 g-5 g. For example, the mass m of the loudspeaker 10 may be within a range of 3.8 g-4.5 g.
In some embodiments, the vibration plate 122 may be connected between the magnetic conductive cover 1232 and the magnet assembly 1231 to elastically support the magnet assembly 1231. In some embodiments, the vibration plate 122 may include a first vibration plate 125 and a second vibration plate 126. As shown in
In some embodiments, the multiple support rods 1251 of the vibration plate 122 may adopt a zigzag bending structure to give the vibration plate a preset elastic coefficient.
In some embodiments, referring to
To resist the magnetic attraction force of the magnet assembly 1231 and prevent magnet offset in the transducer 12, the stiffness of the vibration plate 122 in any direction (hereinafter referred to as the radial direction) within the plane perpendicular to the vibration direction may be greater than a stiffness threshold. For example, the equivalent stiffness in the radial direction of the vibration plate 122 may be greater than 4.7×104 N/m based on the width of the magnetic gap A1 and the magnetic attraction force between the magnet assembly 1231 and the magnetic conductive cover 1232. As another example, the equivalent stiffness in the radial direction of the vibration plate 122 may be greater than 6.4×104 N/m. By optimizing the stiffness in the length and width directions of the elastic vibration plate 122 within the plane perpendicular to the vibration direction, it may resist the magnetic attraction force of the magnet assembly 1231, thus preventing magnet offset in the transducer 12, which means preventing collisions between the coil and movable parts of the magnetic circuit system 123.
It should be noted that the transducer 12 provided in the present disclosure may include at least one vibration plate, and the at least one vibration transmission plate is connected between the magnet assembly 1231 and the magnetic conductive cover 1232. The equivalent stiffness in the radial direction of the at least one vibration plate is greater than 4.7×104 N/m. For example, the transducer 12 may only include at least one vibration plate 122. As another example, the transducer 12 may only include at least two vibration plates 122, namely a first vibration plate 125 and a second vibration plate 126. The equivalent stiffness in the radial direction of each of the first vibration plate 125 and the second vibration plate 126 may be greater than 4.7×104 N/m.
In some embodiments, dimensional data of the vibration plate 122 may be determined based on the requirements for its equivalent stiffness in the radial direction. In some embodiments, a ratio of a distance between a starting point and an ending point of the support rod 1251 along the length direction of the vibration plate 122 to a length of the support rod 1251 itself may be within a range of 0-1.2. The distance between the starting point and the ending point of the support rod 1251 along the length direction of the vibration plate 122 refers to a distance along the length direction of the vibration plate 122 between a connection point of the support rod 1251 with the central region 1252 of the vibration plate and a connection point of the support rod 1251 with the edge region 1253 of the vibration plate. For example, as shown in
In some embodiments, the length of the support rod 1251 may be within a range of 7 mm-25 mm. In some embodiments, a thickness of the support rod along the axial direction of the transducer 12 (i.e., the thickness of the vibration plate) may be within a range of 0.1 mm-0.2 mm. In some embodiments, a ratio range of the thickness of the vibration plate along the axial direction of the transducer 12 to the width of any support rod 1251 along a radial plane of the transducer 12 may be within a range of 0.16-0.75. Exemplary ratio ranges of thickness to width may include: 0.2-0.7, 0.26-0.65, 0.3-0.6, 0.36-0.55, or 0.4-0.5, etc. In some embodiments, the thickness of the first vibration plate 125 may be within a range of 0.1 mm-0.2 mm, and a width range of the support rod 1251 may be within a range of 0.25 mm-0.5 mm. For example, a thickness range of the first vibration plate 125 may be within a range of 0.1 mm-0.15 mm, and a width range of the support rod 1251 may be within a range of 0.4 mm-0.48 mm.
In some embodiments, the loudspeaker 10 may include an air-conduction loudspeaker and a bone-conduction loudspeaker (e.g., as shown in
In some embodiments, to make the resonance peak frequency of the transducer 12 less than 300 Hz, a ratio range of a total axial (parallel to the vibration direction) elastic coefficient k of the vibration plate 122 to the mass m of the transducer 12 may be set as: k/m<(2π·300)2≈3.6×106 Hz2. In some embodiments, the mass of the transducer 12 may include the sum of the masses of the magnetic conductive cover 1232, the coil 124, and the housing 11, or the sum of the masses of the air-conduction loudspeaker 16, the magnetic conductive cover 1232, the coil 124, and the housing 11. The unit of the elastic coefficient k is N/m (Newton per meter), and the unit of the mass m is g (gram).
In some embodiments, to reduce the overall size and mass of the device and improve sound quality, the mass m of the transducer 12 may be within a range of 2 g to 5 g. For example, the mass of the transducer 12 may be within a range of 2.2 g to 4.8 g. As another example, the mass of the transducer 12 may be within a range of 3.8 g to 4.5 g.
In some embodiments, based on the mass range of the transducer 12 and the ratio range of the total axial elastic coefficient k of the vibration plate 122 to the mass m of the transducer 12, the total axial elastic coefficient k of the vibration plate 122 may be determined to be less than 18000 N/m. In some embodiments, the vibration plate 122 includes a parallel connection of the first vibration plate 125 and the second vibration plate 126 as shown in
Therefore, by adjusting the mass range of the mass block connected by the double vibration plates consisting of the first vibration plate 125 and the second vibration plate 126, and/or adjusting the elastic coefficients of the double vibration plates, the bone-conduction resonance peak frequency may be achieved at no more than 300 Hz. It should be noted here that the mass of the mass block refers to the mass of all components that need to be driven by the double vibration plates. For example, in the embodiment shown in
Therefore, by adjusting the mass range of the mass block connected by the double vibration plates consisting of the first vibration plate 125 and the second vibration plate 126 and/or the elastic coefficients of the double vibration plates, the bone-conduction resonance peak frequency may be achieved at no more than 300 Hz. It should be noted here that the mass of the mass block refers to the mass of all components that need to be driven by the double vibration plates. For example, in the embodiment shown in
In some embodiments, the magnet 1233, the magnetic conductive plate, or the magnetic conductive cover 1232 may have arrays composed of multiple magnetic parts with different magnetization directions. In some embodiments, the magnetization directions of the multiple magnetic parts rotate clockwise or counterclockwise on a surface parallel to the vibration direction of the transducer 12. As shown in
The potential beneficial effects of the embodiments described in the present disclosure include, but are not limited to: (1) by setting a count of coils 124 along the radial direction of the transducer 12 as an even number, the inlet position and the outlet position of the first coil 1241 or the second coil 1242 are located at the same position of the magnetic conductive cover 1232, thereby allowing the inner wall of the magnetic conductive cover 1232 to fit with the outer wall of the coil 124, and reducing the mass of the transducer 12 (and subsequently reducing the mass of the loudspeaker 10); (2) by shaping the coil 124 (first coil 1241 and second coil 1242) into a “slender” form and selecting suitable parameters for the coil 124, the inner diameter of the magnetic conductive cover 1232 may be reduced, further reducing the mass of the transducer 12 (and subsequently reducing the mass of the loudspeaker 10); (3) by setting a weight-reducing slot on the magnetic conductive cover 1232 or by drilling a hole in the magnet 1233 and/or the magnetic conductive plate (the first magnetic conductive plate 1234 and/or the second magnetic conductive plate 1235), the mass of the transducer 12 may be reduced (and subsequently reducing the mass of the loudspeaker 10); (4) by adjusting the total axial elastic coefficient of the loudspeaker 10 and the vibration plate 122, the bone-conduction resonance peak frequency may be kept below 300 Hz, thereby preventing the bone-conduction loudspeaker from vibrating at low frequencies and causing users to feel significant vibrations; (5) by setting the stiffness of the vibrating plate 122 in any direction (radial direction) perpendicular to the vibration direction, it may resist the magnetic attraction of the magnet assembly 1231, thereby preventing magnet offset in the transducer 12; (6) by setting the ratio of the thickness of the magnetic conductive plate to the thickness of the magnet 1233, the magnetic field intensity may be increased while avoiding magnetic saturation, thereby enhancing the sensitivity of the loudspeaker 10; (7) by setting magnetic segment arrays with different magnetization directions in at least one of the magnet 1233, the magnetic conductive plate, and/or the magnetic conductive cover 1232, the magnetic field intensity may be improved, thereby further enhancing the sensitivity of the loudspeaker 10; (8) by adopting a dual-coil configuration (the first coil 1241 and the second coil 1242), dual drive is achieved, and the high-frequency impedance of the coils is reduced, thus improving the sensitivity of the transducer 12; (9) by fixing double vibration plates (i.e., the vibration plate 122 includes a first vibration plate 125 and a second vibration plate 126) on both sides of the magnet 1233, it ensures high-sensitivity output while maintaining stable vibration of the magnet 1233 through the support of the double vibration plates; (10) the coil 124 is attached to the magnetic conductive cover 1232, making the magnetic gap between the magnetic conductive cover 1232 and the coil 124 smaller, thus concentrating the magnetic field and improving the sensitivity of the transducer 12.
The basic concepts have been described above, apparently, in detail, as will be described above, and does not constitute limitations of the disclosure. Although there is no clear explanation here, those skilled in the art may make various modifications, improvements, and modifications of present disclosure. This type of modification, improvement, and corrections are recommended in present disclosure, so the modification, improvement, and the amendment remain in the spirit and scope of the exemplary embodiment of the present disclosure.
At the same time, present disclosure uses specific words to describe the embodiments of the present disclosure. As “one embodiment”, “an embodiment”, and/or “some embodiments” means a certain feature, structure, or characteristic of at least one embodiment of the present disclosure. Therefore, it is emphasized and should be appreciated that two or more references to “an embodiment” or “one embodiment” or “an alternative embodiment” in various parts of present disclosure are not necessarily all referring to the same embodiment. Further, certain features, structures, or features of one or more embodiments of the present disclosure may be combined.
In addition, unless clearly stated in the claims, the order of processing elements and sequences, the use of numbers and letters, or the use of other names in the present disclosure are not used to limit the order of the procedures and methods of the present disclosure. Although the above disclosure discusses through various examples what is currently considered to be a variety of useful embodiments of the disclosure, it is to be understood that such detail is solely for that purpose, and that the appended claims are not limited to the disclosed embodiments, but, on the contrary, are intended to cover modifications and equivalent arrangements that are within the spirit and scope of the disclosed embodiments. For example, although the implementation of various components described above may be embodied in a hardware device, it may also be implemented as a software only solution, e.g., an installation on an existing server or mobile device.
Similarly, it should be appreciated that in the foregoing description of embodiments of the present disclosure, various features are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure aiding in the understanding of one or more of the various embodiments. However, this disclosure does not mean that the present disclosure object requires more features than the features mentioned in the claims. Rather, claimed subject matter may lie in less than all features of a single foregoing disclosed embodiment.
In some embodiments, the numbers expressing quantities of ingredients, properties, and so forth, used to describe and claim certain embodiments of the application are to be understood as being modified in some instances by the term “about,” “approximate,” or “substantially”. Unless otherwise stated, “about,” “approximate,” or “substantially” may indicate ±20% variation of the value it describes. Accordingly, in some embodiments, the numerical parameters used in the specification and claims are approximate values, and the approximation may change according to the characteristics required by the individual embodiments. In some embodiments, the numerical parameter should consider the prescribed effective digits and adopt a general digit retention method. Although in some embodiments, the numerical fields and parameters used to confirm the breadth of its range are approximate values, in specific embodiments, such numerical values are set as accurately as possible within the feasible range.
With respect to each patent, patent application, patent application disclosure, and other material cited in the present disclosure, such as articles, books, manuals, publications, documents, etc., the entire contents thereof are hereby incorporated by reference into the present disclosure. Application history documents that are inconsistent with the contents of the present disclosure or that create conflicts are excluded, as are documents (currently or hereafter appended to the present disclosure) that limit the broadest scope of the claims of the present disclosure. It should be noted that in the event of any inconsistency or conflict between the descriptions, definitions, and/or use of terms in the materials appended to the present disclosure and those described in the present disclosure, the descriptions, definitions, and/or use of terms in the present disclosure shall prevail.
At last, it should be understood that the embodiments described in the present disclosure are merely illustrative of the principles of the embodiments of the present disclosure. Other modifications that may be employed may be within the scope of the present disclosure. Thus, by way of example, but not of limitation, alternative configurations of the embodiments of the present disclosure may be utilized in accordance with the teachings herein. Accordingly, embodiments of the present disclosure are not limited to that precisely as shown and described.
Number | Date | Country | Kind |
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202210877819.0 | Jul 2022 | CN | national |
This application is a Continuation of International Application No. PCT/CN2022/133200, filed on Nov. 21, 2022, which claims priority to Chinese Patent Application No. CN202210877819.0, filed on Jul. 25, 2022, the entire contents of each of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | PCT/CN2022/133200 | Nov 2022 | WO |
Child | 18767961 | US |