Sound production device, sound production module and electronic equipment
By designing a dual-diaphragm assembly and a dual-voice coil structure, the problem of limited effective sound-generating area in the vibration system was solved, thereby improving sound performance in confined spaces, increasing the sound-generating area, and enhancing sound sensitivity and loudness.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- GOERTEK INC
- Filing Date
- 2026-03-09
- Publication Date
- 2026-06-19
AI Technical Summary
In existing technologies, the effective sound-generating area of vibration systems is limited, resulting in insufficient sound-generating performance, which is particularly difficult to improve when installation space is limited in portable terminals.
The system employs a dual-diaphragm assembly structure. By setting a through hole in the magnetic circuit system and connecting the two diaphragm assemblies with connectors, independent front and rear chambers are formed. A dual voice coil structure is set in the magnetic circuit system to achieve dual-sided vibration linkage for sound generation, thereby increasing the sound-generating area.
Without increasing product size, the sound-generating device's sensitivity and loudness are significantly improved, making it suitable for small installation spaces, increasing the effective sound-generating area, and enhancing the sound-generating effect.
Smart Images

Figure CN122248327A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of electroacoustic transduction technology, and in particular to a sound-generating device, as well as a sound-generating module and electronic device using the sound-generating device. Background Technology
[0002] In recent years, with the rapid development of consumer electronics, miniature speakers, as a common electroacoustic transducer, have been widely used in mobile phones, glasses, headphones, tablets and other fields. These portable terminal products have gradually formed a trend of multi-functionality, miniaturization and high performance.
[0003] Currently, some terminals, especially portable terminals such as mobile phones, tablets, and headphones, offer very limited installation space for speakers. The effective sound-producing area of conventional speakers is limited by the product's external dimensions, and because the diaphragm surround vibrates non-piston, the effective air area propelled by the vibration system cannot exceed the product's external area, thus limiting the effective sound-producing area of the vibration system and consequently restricting its sound performance. Summary of the Invention
[0004] The main objective of this invention is to provide a sound-generating device, a sound-generating module, and an electronic device, which aims to solve the problem of limited effective sound-generating area in existing vibration systems, and to provide a way to significantly increase the effective sound-generating area of the sound-generating device without increasing the product size, thereby improving sound performance.
[0005] To achieve the above objectives, the present invention provides a sound-generating device, the sound-generating device comprising:
[0006] A vibration system that vibrates along a first direction, the vibration system comprising a first diaphragm assembly, a second diaphragm assembly and two voice coils, the first diaphragm assembly and the second diaphragm assembly being spaced apart along the first direction, the two voice coils being parallel and spaced apart along a second direction and both being connected to the first diaphragm assembly, the first direction being perpendicular to the second direction; A magnetic circuit system is provided between the first diaphragm assembly and the second diaphragm assembly. The magnetic circuit system has two magnetic gaps and a through hole penetrating the magnetic circuit system. The through hole is located between the two magnetic gaps. Each voice coil is correspondingly provided with one magnetic gap. A connector, which passes through the through hole, and whose two ends are respectively connected to the first diaphragm assembly and the second diaphragm assembly; and A diaphragm, comprising an outer connecting portion, an inner connecting portion, and a folded ring portion located between the outer connecting portion and the inner connecting portion, wherein the outer connecting portion is connected to the magnetic circuit system and the inner connecting portion is connected to the connector to close the through hole; The first diaphragm assembly forms a first rear cavity with the magnetic circuit system and the diaphragm, the second diaphragm assembly forms a first front cavity with the magnetic circuit system and the diaphragm, and the sound-generating device is also provided with a sound outlet communicating with the first front cavity.
[0007] In one embodiment, the two ends of the connector are respectively bonded to the first diaphragm assembly and the second diaphragm assembly.
[0008] In one embodiment, the connector is a tube with one end open and the other end closed. The connector has an open end and a closed end. The outer diameter of the open end is larger than the outer diameter of the closed end. The second diaphragm assembly is connected to the open end, and the first diaphragm assembly is connected to the closed end. Wherein, the connector bends and extends at the open end to form a bent portion, the bent portion being connected to the second diaphragm assembly; and / or, the magnetic circuit system has a clearance area corresponding to the bent portion; And / or, the connector is provided with a first through hole communicating with the first rear cavity; And / or, the connector is tapered along the first direction; or, the cross-sectional shape of the sidewall of the connector along the first direction is stepped, arc-shaped, or straight.
[0009] In one embodiment, the connector is a hollow cylindrical shape with openings at both ends. The connector has a first end and a second end. One of the first diaphragm assembly and the second diaphragm assembly is connected to the first end, and the other of the first diaphragm assembly and the second diaphragm assembly is connected to the second end. Wherein, the first end is folded to form a first flange; and / or, the second end is folded to form a second flange; And / or, the sidewall of the connector is provided with a recessed or protruding reinforcing portion; And / or, the connector is provided with a second through hole communicating with the first rear cavity; And / or, the connector is tapered along the first direction; or, the cross-sectional shape of the sidewall of the connector along the first direction is stepped, arc-shaped, or straight.
[0010] In one embodiment, the connector includes a first connecting portion, a second connecting portion, and a support portion connected between the first connecting portion and the second connecting portion. The first connecting portion and the second connecting portion are arranged opposite to each other along the first direction, and both the first connecting portion and the second connecting portion extend perpendicularly to the first direction and are elongated. One of the first diaphragm assembly and the second diaphragm assembly is connected to the first connecting portion, and the other of the first diaphragm assembly and the second diaphragm assembly is connected to the second connecting portion. The support portion extends along the first direction; the support portion includes one or more, and the plurality of support portions are arranged at intervals. Alternatively, the support portion may include a first segment extending downward from one end of the first connecting portion, a second segment extending from the lower end of the first segment along the length direction of the first connecting portion toward the other end of the first connecting portion, and a third segment extending downward from the end of the second segment away from the first segment and connected to the second connecting portion. Alternatively, the support portion may include two portions, which are arranged at an angle and cross each other.
[0011] In one embodiment, the first diaphragm assembly includes a first diaphragm and a first diaphragm plate connected to the first diaphragm, and both voice coils are connected to the first diaphragm plate. The second diaphragm assembly includes a second diaphragm and a second diaphragm plate connected to the second diaphragm plate. The connecting member is integrally formed with the first diaphragm plate or the second diaphragm plate. The first vibrating plate has a first protrusion extending toward the through hole, the first protrusion passing through the through hole and connecting to the second diaphragm assembly, the first protrusion forming the connector; or, the second vibrating plate has a second protrusion extending toward the through hole, the second protrusion passing through the through hole and connecting to the first diaphragm assembly, the second protrusion forming the connector.
[0012] In one embodiment, the inner connecting portion is sandwiched between the connector and the first diaphragm assembly or the second diaphragm assembly; Alternatively, the inner connecting part is provided with an inner ring hole, the connector passes through the inner ring hole and the inner connecting part is connected to the outside of the connector to close the through hole; Alternatively, the connector may include two skeletons arranged along the first direction, with the two skeletons respectively disposed on opposite sides of the diaphragm along the first direction. One end of each skeleton extends into the through hole and is connected to the inner connecting portion, and the other end of each skeleton is respectively connected to the first diaphragm assembly and the second diaphragm assembly.
[0013] In one embodiment, the magnetic circuit system includes a magnetic yoke and a common magnetic part, a side magnetic part, and two central magnetic parts disposed on the side of the magnetic yoke facing the first diaphragm assembly. The two central magnetic parts are spaced apart along the second direction. The common magnetic part is located between the two central magnetic parts. The side magnetic part is located outside the common magnetic part and the two central magnetic parts. Each central magnetic part is spaced apart from the side magnetic part and the common magnetic part to form a magnetic gap. The through hole sequentially penetrates the common magnetic part and the magnetic yoke.
[0014] In one embodiment, the common magnetic part includes a common magnet and a common magnetic plate stacked together, the common magnet is connected to the magnetic yoke, and the through hole sequentially passes through the common magnetic plate, the common magnet and the magnetic yoke; The side magnetic part includes a side magnet and a side magnetic plate stacked together, and the side magnet is connected to the magnetic yoke; Each of the central magnetic units includes a central magnet and a central magnetic guide plate stacked together, wherein the central magnet is connected to the magnetic guide yoke; The common magnet, the side magnet, and the two center magnets are all magnetized along the first direction, and the magnetization direction of the two center magnets is opposite to that of the common magnet and the two side magnets.
[0015] In one embodiment, the common magnetic plate has a first stepped portion around the through hole on the side facing away from the common magnet, and the outer periphery of the diaphragm is connected to the first stepped portion; or, the magnetic yoke has a second stepped portion around the through hole on the side facing away from the common magnet, and the outer periphery of the diaphragm is connected to the second stepped portion. And / or, the two ends of the common magnetic part along the third direction are respectively abutted against the side magnetic part, bonded together, or integrally formed, and the first direction, the second direction, and the third direction are perpendicular to each other; And / or, the width of the common magnetic part along the second direction is greater than or equal to 1.5 times the width of the central magnetic part along the second direction.
[0016] In one embodiment, the sound-generating device further includes a housing, the housing having a mounting cavity, the magnetic circuit system being disposed within the mounting cavity, the periphery of the first diaphragm assembly being connected to one end of the housing, and the periphery of the second diaphragm assembly being connected to the other end of the housing; The first diaphragm assembly, the housing, the magnetic circuit system, and the diaphragm together form the first rear cavity, and the second diaphragm assembly, the housing, the magnetic circuit system, and the diaphragm together form the first front cavity. The housing is provided with the sound outlet.
[0017] In one embodiment, the outer casing is further provided with a vent that communicates with the first rear cavity.
[0018] In one embodiment, the outer casing includes a first housing and a second housing arranged sequentially along the first direction, the magnetic circuit system is connected to the first housing and the second housing, the end of the first housing away from the second housing is connected to the periphery of the first diaphragm assembly, the end of the second housing away from the first housing is connected to the periphery of the second diaphragm assembly, and the second housing is provided with the sound outlet; The vent is located in the first housing; or the vent is formed between the first housing and the second housing. And / or, the second housing is provided with a support platform adjacent to the first housing, and the periphery of the magnetic yoke is supported and fixed to the support platform; or, the second housing is an injection molded part, and the second housing and the magnetic yoke are integrally injection molded. And / or, the first housing is a metal part, and the first housing and the side magnetic plate are integrally formed; And / or, the sound outlet and the vent are located on different sides of the housing.
[0019] The present invention also proposes a sound-generating module, the sound-generating module comprising: A module housing, the module housing having a receiving cavity and a module acoustic port communicating with the receiving cavity; and The aforementioned sound-generating device is disposed within the accommodating cavity, a second front cavity is formed between the module housing and the first diaphragm assembly of the sound-generating device, and a second rear cavity is formed between the module housing and the second diaphragm assembly of the sound-generating device. The module's sound hole is connected to the second front cavity, and is connected to the first front cavity of the sound-generating device through the sound outlet of the sound-generating device.
[0020] In one embodiment, the module housing is further provided with module vent holes that communicate with the first rear cavity and the second rear cavity of the sound-generating device, respectively.
[0021] The present invention also proposes an electronic device, which includes the sound-generating device described above; Alternatively, the electronic device may include the sound-generating module described above.
[0022] The sound-generating device of this invention comprises a first diaphragm assembly and a second diaphragm assembly of a vibration system respectively disposed on opposite sides of a magnetic circuit system along a first direction, and spaced apart from the magnetic circuit system. Two magnetic gaps are spaced apart along a second direction within the magnetic circuit system. Two voice coils are spaced apart and arranged in parallel along the second direction, both connected to the first diaphragm assembly. Each voice coil corresponds to one magnetic gap. When an electric current is passed through the two voice coils, the two voice coils convert electrical energy into mechanical energy within the two magnetic gaps formed by the magnetic circuit system, thereby driving the two voice coils. The first diaphragm assembly vibrates along a first direction to produce sound. By using a dual voice coil structure, the voice coil size is increased, raising the L value of the voice coils. This effectively increases the BL value when the two voice coils vibrate in the magnetic field formed by the magnetic circuit system, thereby improving the sound-producing device's sensitivity and loudness, and enhancing the sound production effect. Simultaneously, a through-hole is provided in the magnetic circuit system, located between two magnetic gaps. A connector passes through this through-hole, allowing its two ends to connect to the first and second diaphragm assemblies respectively. The diaphragm and the magnetic circuit system are then connected... The connector is used to seal the through hole, meaning the through hole, connector, and diaphragm are located between the two voice coils and two magnetic gaps. This forms a first rear cavity between the first diaphragm assembly, the magnetic circuit system, and the diaphragm, and a first front cavity between the second diaphragm assembly, the magnetic circuit system, and the diaphragm. The sound-generating device has a sound outlet communicating with the first front cavity. This achieves a structure that uses two sets of vibration structures but only one magnetic circuit system to achieve coordinated sound generation of the dual-sided diaphragm assemblies. This not only occupies a small volume and can adapt to relatively small installation spaces, making it suitable for widespread application in portable terminals, but also utilizes the dual-vibration structure... This effectively increases the sound-generating area, thereby improving sound performance. Furthermore, when the sound-generating device is working, the magnetic circuit system directly drives the two voice coils to vibrate the first diaphragm assembly, and simultaneously drives the second diaphragm assembly to achieve synchronous sound generation through the connector in the through hole. The two through holes are sealed by diaphragms, which isolates the first rear cavity and the first front cavity from each other, avoiding cross-influence of airflow. This allows the sound waves radiated by the second diaphragm assembly to the first front cavity and the sound waves radiated by the first diaphragm assembly to the side away from the first rear cavity to radiate outwards simultaneously, thereby achieving sound wave superposition and further improving the sound generation effect. Attached Figure Description
[0023] To more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0024] Figure 1A schematic diagram of the structure of an embodiment of the sound-generating device provided by the present invention; Figure 2 A cross-sectional schematic diagram along a second direction of an embodiment of the sound-generating device provided by the present invention; Figure 3 A cross-sectional schematic diagram along a third direction of an embodiment of the sound-generating device provided by the present invention; Figure 4 A cross-sectional schematic diagram along a second direction for another embodiment of the sound-generating device provided by the present invention; Figure 5 This is a partially exploded schematic diagram of an embodiment of the sound-generating device provided by the present invention. Figure 6 A schematic diagram of the connection between the outer shell and the magnetic circuit system in one embodiment of the sound-generating device provided by the present invention; Figure 7 for Figure 6 A schematic diagram of the decomposition process; Figure 8 A cross-sectional schematic diagram of the magnetic circuit system and voice coil provided by the present invention; Figure 9 A schematic diagram of the structure of the first diaphragm assembly, diaphragm, connector and second diaphragm assembly in one embodiment of the sound generating device provided by the present invention; Figure 10 This is a schematic diagram of the structure of the first embodiment of the connector provided by the present invention; Figure 11 for Figure 10 A cross-sectional schematic diagram; Figure 12 This is a cross-sectional schematic diagram of a second embodiment of the connector provided by the present invention; Figure 13 This is a cross-sectional schematic diagram of the third embodiment of the connector provided by the present invention; Figure 14 This is a cross-sectional schematic diagram of the fourth embodiment of the connector provided by the present invention; Figure 15 This is a structural schematic diagram of the fifth embodiment of the connector provided by the present invention; Figure 16 This is a schematic diagram of the sixth embodiment of the connector provided by the present invention; Figure 17 A schematic diagram of the seventh embodiment of the connector provided by the present invention; Figure 18 A schematic diagram of the structure of the eighth embodiment of the connector provided by the present invention; Figure 19 A schematic diagram of the structure of the ninth embodiment of the connector provided by the present invention; Figure 20 This is a structural schematic diagram of the tenth embodiment of the connector provided by the present invention; Figure 21 This is a schematic diagram of the eleventh embodiment of the connector provided by the present invention; Figure 22 This is a schematic diagram of the structure of the twelfth embodiment of the connector provided by the present invention; Figure 23 This is a cross-sectional schematic diagram of an embodiment of the diaphragm provided by the present invention; Figure 24 A cross-sectional schematic diagram of another embodiment of the diaphragm provided by the present invention; Figure 25 A cross-sectional schematic diagram of yet another embodiment of the diaphragm provided by the present invention; Figure 26 This is a cross-sectional schematic diagram along the second direction of an embodiment of the sound-generating module provided by the present invention.
[0025] Explanation of icon numbers: 100. Sound-generating device; 1. Housing; 11. First housing; 12. Second housing; 121. Support platform; 122. Sound outlet; 13. Vent; 2. Magnetic circuit system; 21. Magnetic yoke; 211. Clearance area; 22. Central magnetic part; 221. Central magnet; 222. Central magnetic plate; 23. Side magnetic part; 231. Side magnet; 232. Side magnetic plate; 24. Magnetic gap; 25. Through hole; 26. Common magnetic part; 261. Common magnet; 262. Common magnetic plate; 263. First step part; 3. Vibration system; 31. First diaphragm assembly; 311. First diaphragm; 312. First vibrating plate; 32. Second diaphragm assembly; 321. Second diaphragm; 322. Second vibrating plate; 33. Sound... 34. Centering support plate; 4. Connector; 411. Open end; 412. Closed end; 413. Bending part; 414. Frame; 421. First end; 422. First flange; 423. Second end; 424. Second flange; 425. Reinforcing part; 431. First connecting part; 432. Second connecting part; 433. Support part; 434. First section; 435. Second section; 436. Third section; 5. Diaphragm; 52. Folded ring part; 54. Inner connecting part; 541. Inner ring hole; 55. Outer connecting part; 6. First rear cavity; 7. First front cavity; 800. Module housing; 801. Second front cavity; 802. Second rear cavity; 803. Module sound hole; 804. Module vent hole; 900. Sound-generating module.
[0026] The realization of the objective, functional features and advantages of the present invention will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0027] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present invention.
[0028] It should be noted that all directional indications (such as up, down, left, right, front, back, etc.) in the embodiments of the present invention are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indication will also change accordingly.
[0029] Meanwhile, the meaning of "and / or" or "and / or" appearing throughout the text is that it includes three options. Taking "A and / or B" as an example, it includes option A, option B, or an option that satisfies both A and B.
[0030] Furthermore, in this invention, descriptions involving "first," "second," etc., are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of that feature. Additionally, the technical solutions of the various embodiments can be combined with each other, but only on the basis of being achievable by those skilled in the art. When the combination of technical solutions is contradictory or impossible to implement, such a combination of technical solutions should be considered non-existent and not within the scope of protection claimed by this invention.
[0031] This invention proposes a sound-generating device 100, which is applied in an electronic device. It is understood that the electronic device can be a mobile phone, headphones, smart wearable devices, smart glasses, etc., and is not limited thereto.
[0032] Please refer to the reference. Figures 1 to 25As shown, in this embodiment of the invention, the sound-generating device 100 includes a vibration system 3, a magnetic circuit system 2, a connector 4, and a diaphragm 5. The vibration system 3 vibrates along a first direction and includes a first diaphragm assembly 31, a second diaphragm assembly 32, and two voice coils 33. The first diaphragm assembly 31 and the second diaphragm assembly 32 are spaced apart along the first direction, and the two voice coils 33 are parallel and spaced apart along a second direction, and are both connected to the first diaphragm assembly 31. The first direction is perpendicular to the second direction. The magnetic circuit system 2 is located between the first diaphragm assembly 31 and the second diaphragm assembly 32. The magnetic circuit system 2 has two magnetic gaps 24 and a through hole 25 penetrating the magnetic circuit system 2. The through hole 25 is located between the two magnetic gaps 24. Each voice coil 33 is correspondingly provided with a magnetic gap 24. The connector 4 passes through the through hole 25, and the two ends of the connector 4 are respectively connected to the first diaphragm assembly 31 and the second diaphragm assembly 32. The diaphragm 5 includes an outer connecting part 55, an inner connecting part 54, and a folded ring part 52 located between the outer connecting part 55 and the inner connecting part 54. The outer connecting part 55 is connected to the magnetic circuit system 2, and the inner connecting part 54 is connected to the connector 4 to close the through hole 25. The first diaphragm assembly 31 forms a first rear cavity 6 between the magnetic circuit system 2 and the diaphragm 5, and the second diaphragm assembly 32 forms a first front cavity 7 between the magnetic circuit system 2 and the diaphragm 5. The sound generating device 100 is also provided with a sound outlet 122 communicating with the first front cavity 7.
[0033] In this embodiment, the sound-generating device 100 can be a single unit of a loudspeaker, and the loudspeaker can be a miniature loudspeaker. It is understood that, to facilitate the installation of the magnetic circuit system 2 and vibration system 3 of the sound-generating device 100, the sound-generating device 100 also includes a housing 1, in which both the magnetic circuit system 2 and vibration system 3 are housed. Thus, the housing 1 is used to install, fix, and support the magnetic circuit system 2 and vibration system 3. This not only enables the installation and fixation of the magnetic circuit system 2 and vibration system 3 but also provides protection for them.
[0034] Understandably, the outer casing 1 has a mounting cavity, and both the magnetic circuit system 2 and the vibration system 3 are housed within the receiving cavity of the outer casing 1. In this embodiment, as... Figures 2 to 8 As shown, the magnetic circuit system 2 is located inside the mounting cavity, the periphery of the first diaphragm assembly 31 is connected to one end of the housing 1, and the periphery of the second diaphragm assembly 32 is connected to the other end of the housing 1.
[0035] In this embodiment, a first rear cavity 6 is formed between the first diaphragm assembly 31 and the magnetic circuit system 2, that is, the first diaphragm assembly 31, the outer shell 1, the magnetic circuit system 2 and the diaphragm 5 enclose and form the first rear cavity 6. A first front cavity 7 is formed between the second diaphragm assembly 32 and the magnetic circuit system 2, that is, the second diaphragm assembly 32, the outer shell 1, the magnetic circuit system 2 and the diaphragm 5 enclose and form the first front cavity 7.
[0036] Understandably, the sound-generating device 100 also has a sound outlet 122 communicating with the first front cavity 7. This allows the sound waves radiated by the second diaphragm assembly 32 towards the first front cavity 7 to radiate outwards through the sound outlet 122, and the sound waves radiated by the first diaphragm assembly 31 away from the first rear cavity 6 to also radiate outwards. At this time, the sound waves radiated outwards by the first diaphragm assembly 31 and the sound waves radiated outwards by the second diaphragm assembly 32 through the sound outlet 122 can be superimposed, thereby increasing the effective sound-generating area and improving the acoustic performance of the sound-generating device 100. In this embodiment, as... Figure 1 , Figure 3 , Figures 5 to 8 As shown, the outer casing 1 is provided with a sound outlet 122.
[0037] In this embodiment, for the sake of simplicity, the position of the first diaphragm assembly 31 of the sound-generating device 100 when it is placed facing upwards is used as a reference to define the upper and lower positions, that is, the side of the first diaphragm assembly 31 facing away from the magnetic circuit system 2 is upper, and the side of the second diaphragm assembly 32 facing away from the magnetic circuit system 2 is lower.
[0038] It should be noted that the outer contour of the sound-generating device 100 can be a circular, elliptical, or square polygonal structure, and is not limited here. In this embodiment, the sound-generating device 100 may optionally be square. The vibration direction of the first diaphragm assembly 31 and the second diaphragm assembly 32 of the vibration system 3 is defined as the first direction, and the first direction is defined as the Z-axis direction (that is, the thickness direction of the sound-generating device 100). The length direction of the sound-generating device 100 is defined as the second direction, and the second direction is defined as the X-axis direction. The width direction of the sound-generating device 100 is defined as the third direction, and the third direction is defined as the Y-axis direction. The first direction, the second direction, and the third direction are arranged perpendicularly to each other, such as... Figures 1 to 8 As shown, no limitations are specified here. It is understood that the planes containing the second and third directions are perpendicular to the first direction. It is also understood that the vertical directions coincide with or are parallel to the first direction.
[0039] To facilitate the assembly of the magnetic circuit system 2 and the vibration system 3, the outer casing 1 may optionally be a split structure. In this embodiment, as... Figures 1 to 8 As shown, the outer casing 1 includes a first casing 11 and a second casing 12 arranged sequentially along a first direction, and the first casing 11 and the second casing 12 enclose each other to form an installation cavity.
[0040] Optionally, the magnetic circuit system 2 is connected to the first housing 11 and the second housing 12. The end of the first housing 11 away from the second housing 12 is connected to the periphery of the first diaphragm assembly 31, and the end of the second housing 12 away from the first housing 11 is connected to the periphery of the second diaphragm assembly 32. In this embodiment, the second housing 12 is provided with a sound outlet 122.
[0041] In this embodiment, the outer shell 1 can be a square frame structure, that is, both the first shell 11 and the second shell 12 are square frame structures. The first shell 11 is used to support and fix the first diaphragm assembly 31 so as to support the first diaphragm assembly 31 away from the magnetic circuit system 2. The second shell 12 is used to support and fix the second diaphragm assembly 32 so as to support the second diaphragm assembly 32 away from the magnetic circuit system 2. In this way, the first diaphragm assembly 31 and the second diaphragm assembly 32 are opposite to and spaced apart from the magnetic circuit system 2, thereby facilitating the vibration and sound generation of the first diaphragm assembly 31 and the second diaphragm assembly 32.
[0042] It should be noted that the first housing 11 and the second housing 12 of the outer casing 1 can be connected by adhesive bonding or welding, and there is no limitation on this. Optionally, the first housing 11 and the second housing 12 are bonded together.
[0043] To further improve the connection strength, in one embodiment, the sound-generating device 100 also includes a fixing member extending along a first direction, with one end of the fixing member connected to the first housing 11 and the other end connected to the second housing 12. In this embodiment, the first housing 11 and the second housing 12 are connected by the fixing member. The fixing member is welded or bonded to the first housing 11 and the second housing 12. This arrangement improves the connection strength and enhances the drop resistance of the sound-generating device 100.
[0044] Optionally, the sound outlet 122 includes multiple outlets, which facilitates the smooth and rapid flow of sound waves, thereby improving the sound production effect.
[0045] It should be noted that, in order to ensure the vibration performance of the vibration system 3 and maintain air pressure balance on the opposite sides of the first diaphragm assembly 31 and the opposite sides of the second diaphragm assembly 32, in this embodiment, the sound-generating device 100 is provided with a vent 13 communicating with the first rear cavity 6. It is understood that the outer shell 1 is also provided with a vent 13 communicating with the first rear cavity 6 to achieve air release, which is not limited here.
[0046] In this embodiment, as Figure 3 , Figures 5 to 7 As shown, the vent 13 is located on the first housing 11. Of course, in other embodiments, the vent 13 is formed between the first housing 11 and the second housing 12, which is not limited here. Optionally, multiple vents 13 are included, which facilitates smooth and rapid airflow, thereby improving the sound production effect. Optionally, the sound outlet 122 and the vent 13 are located on different sides of the housing 1 to avoid the sound waves radiated from the sound outlet 122 and the sound waves radiated from the vent 13 canceling each other out and affecting the sound production effect of the sound-producing device 100. Specifically, along the circumference of the housing 1, a sound outlet 122 is provided on one side of the housing 1, and multiple vents 13 are provided on the remaining sides of the housing 1.
[0047] Understandably, the first diaphragm assembly 31 and the second diaphragm assembly 32 can refer to existing forms. Both voice coils 33 are connected to the first diaphragm assembly 31 and extend into the two magnetic gaps 24 of the magnetic circuit system 2. The changing current flowing through the two voice coils 33 causes them to vibrate under different magnitudes of Ampere force, thus causing the two voice coils 33 to vibrate and drive the first diaphragm assembly 31 to vibrate. The energy conversion method is electrical energy to mechanical energy to acoustic energy. The form of the magnetic circuit system 2 can also refer to existing structures. The top view outline of the magnetic circuit system 2 can be circular or rounded rectangle, etc.
[0048] In this embodiment, as Figures 1 to 9As shown, by configuring the vibration system 3 as a first diaphragm assembly 31 and a second diaphragm assembly 32 that are opposite to and spaced apart along a first direction, and by configuring the magnetic circuit system 2 between the first diaphragm assembly 31 and the second diaphragm assembly 32, which are opposite to and spaced apart from both the first diaphragm assembly 31 and the second diaphragm assembly 32, and by configuring two voice coils 33 that are spaced apart and parallel along a second direction, both of which are connected to the first diaphragm assembly 31, and by configuring two magnetic gaps 24 that are spaced apart along the second direction in the magnetic circuit system 2, each of the two voice coils 33 is correspondingly configured with one magnetic gap 24, and by passing current through the two voice coils 33, the two voice coils... Within the two magnetic gaps 24 formed by the magnetic circuit system 2, electrical energy is converted into mechanical energy to drive the two voice coils 33 to vibrate the first diaphragm assembly 31 in the first direction, thereby producing sound. Furthermore, by setting a double voice coil structure, the voice coil size is increased, and the L value of the voice coils is improved. This effectively increases the BL value when the two voice coils 33 vibrate in the magnetic field formed by the magnetic circuit system 2, thereby improving the sound sensitivity and loudness of the sound-producing device 100 and enhancing the sound production effect. Simultaneously, by setting a through hole 25 through the magnetic circuit system 2, with the through hole 25 located between the two magnetic gaps 24, the connector 4 is inserted into the through hole 25, allowing the two ends of the connector 4 to... The first diaphragm assembly 31 and the second diaphragm assembly 32 are connected to each other respectively, and a diaphragm 5 is provided at the through hole 25. The diaphragm 5 is connected to the magnetic circuit system 2 and the connector 4 to close the through hole 25. That is, the through hole 25, the connector 4 and the diaphragm 5 are located between the two voice coils 33 and the two magnetic gaps 24, so that the first diaphragm assembly 31 forms a first rear cavity 6 between the magnetic circuit system 2 and the diaphragm 5, and the second diaphragm assembly 32 forms a first front cavity 7 between the magnetic circuit system 2 and the diaphragm 5. The sound-generating device 100 is provided with a sound outlet 122 communicating with the first front cavity 7. In this way, the magnetic field generated by the magnetic circuit system 2 acts on the two voice coils 33 to drive the two voice coils 33. The first diaphragm assembly 31 vibrates along the first direction. At this time, since the two ends of the connector 4 are respectively connected to the first diaphragm assembly 31 and the second diaphragm assembly 32, the first diaphragm assembly 31 drives the second diaphragm assembly 32 to achieve synchronous sound generation through the connector 4. This achieves a structure that uses two sets of vibration structures (i.e., the first diaphragm assembly 31 and the second diaphragm assembly 32) but only one set of magnetic circuit system 2 to achieve the linkage sound generation of the double-sided diaphragm assemblies. This structure not only occupies a small volume and can adapt to relatively small installation spaces, making it easy to be widely used in portable terminals, but also effectively increases the sound generation area by utilizing the dual vibration structure, thereby improving the sound generation performance of the sound generation device 100.
[0049] Understandably, when the sound-generating device 100 of the present invention is working, the magnetic circuit system 2 first directly drives the two voice coils 33 to vibrate the first diaphragm assembly 31. Since the diaphragm 5 is used to close the through hole 25, the first rear cavity 6 of the first diaphragm assembly 31 and the first front cavity 7 of the second diaphragm assembly 32 are isolated from each other and the sound waves and airflow do not affect each other. Furthermore, the sound waves radiated by the second diaphragm assembly 32 toward the first front cavity 7 and the sound waves radiated by the first diaphragm assembly 31 toward the side away from the first rear cavity 6 (the sound waves radiated by the upward vibration of the first diaphragm assembly 31) are radiated outward at the same time, thereby achieving sound wave superposition to further improve the sound generation effect of the sound-generating device 100.
[0050] In this embodiment, to ensure the vibration performance of the first diaphragm assembly 31 and the second diaphragm assembly 32 of the vibration system 3, the heights of the first rear cavity 6 and the first front cavity 7 along the first direction are greater than or equal to the amplitudes of the vibrations of the first diaphragm assembly 31 and the second diaphragm assembly 32 along the first direction. It is understood that the phase of the sound wave radiated by the first diaphragm assembly 31 into the first rear cavity 6 is opposite to the phase of the sound wave radiated by the second diaphragm assembly 32 into the first front cavity 7. That is, the phase of the sound wave radiated upwards by the first diaphragm assembly 31 is the same as the phase of the sound wave radiated by the second diaphragm assembly 32 into the first front cavity 7, and the phase of the sound wave radiated by the first diaphragm assembly 31 into the first rear cavity 6 is the same as the phase of the sound wave radiated downwards by the second diaphragm assembly 32. When the sound-generating device 100 is applied to an electronic device, the sound waves radiated upwards by the first diaphragm assembly 31 and the sound waves radiated into the first front cavity 7 by the second diaphragm assembly 32 can be radiated outwards through structures such as the sound outlet channel, thereby achieving sound wave superposition and improving sound generation performance.
[0051] In one embodiment, the magnetic circuit system 2 includes a magnetic yoke 21 and a common magnetic part 26, a side magnetic part 23, and two central magnetic parts 22 disposed on the side of the magnetic yoke 21 facing the first diaphragm assembly 31. The two central magnetic parts 22 are spaced apart along a second direction. The common magnetic part 26 is located between the two central magnetic parts 22. The side magnetic part 23 is located outside the common magnetic part 26 and the two central magnetic parts 22. Each central magnetic part 22 is spaced apart from the side magnetic part 23 and the common magnetic part 26 to form a magnetic gap 24. A through hole 25 passes through the common magnetic part 26 and the magnetic yoke 21 in sequence.
[0052] In this embodiment, as Figures 2 to 8As shown, the magnetic circuit system 2 is configured as a magnetic yoke 21, and a common magnetic part 26, a side magnetic part 23, and two central magnetic parts 22 disposed on the magnetic yoke 21. The two central magnetic parts 22 are spaced apart along the second direction. The common magnetic part 26 is located between the two central magnetic parts 22, and the side magnetic part 23 is located outside the common magnetic part 26 and the two central magnetic parts 22. Each central magnetic part 22 is spaced apart from the side magnetic part 23 and the common magnetic part 26 to form a magnetic gap 24, such that each of the two voice coils 33 corresponds to a magnetic gap 24. The configuration involves passing current through the two voice coils 33, causing them to convert electrical energy into mechanical energy within the two magnetic gaps 24 formed by the magnetic circuit system 2. This mechanical energy drives the two voice coils 33 to vibrate the first diaphragm assembly 31 in the first direction, thereby producing sound. Furthermore, by setting up a dual voice coil structure, the voice coil size is increased, and the L value of the voice coils is improved. This effectively increases the BL value when the two voice coils 33 vibrate in the magnetic field formed by the magnetic circuit system 2, thereby improving the sound sensitivity and loudness of the sound-producing device 100 and enhancing the sound production effect.
[0053] Understandable, such as Figures 2 to 8 As shown, the common magnetic part 26 of the magnetic circuit system 2 is disposed between the two central magnetic parts 22, and one central magnetic part 22, the common magnetic part 26, and the other central magnetic part 22 are arranged at intervals along the second direction. The side magnetic part 23 is disposed outside the common magnetic part 26 and the two central magnetic parts 22, such that each central magnetic part 22 is spaced apart from the side magnetic part 23 and the common magnetic part 26 to form a magnetic gap 24 for accommodating a voice coil 33. Optionally, at least one of each central magnetic part 22, the side magnetic part 23, and the common magnetic part 26 is provided with a permanent magnet. In this embodiment, each voice coil 33 is arranged around a central magnetic part 22.
[0054] Optionally, the through hole 25 passes through the common magnetic part 26 and the magnetic yoke 21 in sequence, that is, the through hole 25 is located between the two central magnetic parts 22. Since the amplitude of the central part of the first diaphragm assembly 31 corresponding to the two central magnetic parts 22 is usually the largest, by using the connector 4 in the through hole 25 to fix the central part of the first diaphragm assembly 31 to the central part of the second diaphragm assembly 32, it is possible to make it easier for the first diaphragm assembly 31 to push the second diaphragm assembly 32.
[0055] Understandably, each central magnetic part 22 may include a central magnet 221 or a sidewall of the magnetic yoke 21; the side magnetic part 23 may be a side magnet 231 or a sidewall of the magnetic yoke 21; and the common magnetic part 26 may be a common magnet 261 or a sidewall of the magnetic yoke 21. At least one of the central magnetic part 22, side magnetic part 23, and common magnetic part 26 is provided with a permanent magnet, which ensures the magnetic stability of the magnetic circuit system 2, thereby providing a more stable magnetic field. This results in more stable vibration of the first diaphragm assembly 31, ensuring the stability of the sound output of the sound-generating device 100.
[0056] Understandably, this is to ensure that the phases of the radiated sound waves from the first diaphragm assembly 31 and the second diaphragm assembly 32 are the same or substantially the same. Optionally, the first diaphragm assembly 31 and the second diaphragm assembly 32 are arranged symmetrically with respect to the magnetic circuit system 2, which is not limited here.
[0057] It should be noted that the form of the through hole 25 can be on the magnetic circuit system 2, as long as it allows the connector 4 to move easily in the through hole 25 to realize the linkage between the first diaphragm assembly 31 and the second diaphragm assembly 32, and the inner wall surface of the connector 4 and the corresponding through hole 25 can provide clearance for the vibration of the diaphragm 5. There are no restrictions here.
[0058] In this embodiment, the through hole 25 is located between the two magnetic gaps 24, that is, between the two voice coils 33. Optionally, the through hole 25 is located in the center of the magnetic circuit system 2. This does not affect the performance of the magnetic circuit system 2 and the setting is simpler and easier to implement. Of course, in other embodiments, the through hole 25 can also be located inside the magnetic gaps 24, which is not limited here. As long as the connector 4 can move freely in the through hole 25 to realize the linkage between the first diaphragm assembly 31 and the second diaphragm assembly 32, and the inner wall surface of the connector 4 and the through hole 25 can provide clearance for the vibration of the diaphragm 5, it is not limited here.
[0059] In one embodiment, the connector 4 is a tube with one end open and the other end closed. The connector 4 has an open end 411 and a closed end 412. The outer diameter of the open end 411 is larger than the outer diameter of the closed end 412. The second diaphragm assembly 32 is connected to the open end 411, and the first diaphragm assembly 31 is connected to the closed end 412.
[0060] In this embodiment, as Figures 2 to 5 , Figures 10 to 17 As shown, the connector 4 has an open end 411 and a closed end 412 along the first direction, that is, one end of the connector 4 is open and the other end is closed, so that the interior of the connector 4 is a hollow structure.
[0061] Understandably, by making the outer diameter of the open end 411 of the connector 4 larger than the outer diameter of the closed end 412, and connecting the second diaphragm assembly 32 to the open end 411 and the first diaphragm assembly 31 to the closed end 412, the support force on the second diaphragm assembly 32 can be increased, thereby improving the vibration stability of the second diaphragm assembly 32 and the vibration system 3. Simultaneously, it ensures the structural strength of the connector 4 during transmission and reduces energy loss by reducing mass. It should be noted that the transmission of the connector 4 refers to pushing or pulling the second diaphragm assembly 32 with the first diaphragm assembly 31 as a reference.
[0062] Of course, in other embodiments, the second diaphragm assembly 32 may be connected to the closed end 412, and the first diaphragm assembly 31 may be connected to the open end 411; this is not limited here.
[0063] Optionally, the closed end 412 of the connector 4 has a connecting plane, which connects to one of the first diaphragm assembly 31 and the second diaphragm assembly 32, thereby effectively increasing the connection area and improving connection stability. It is understood that the open end 411 of the connector 4 is the exposed end; the connector 4 can be open at both ends, or open at one end and closed at the other, without limitation.
[0064] To further increase the connection area of the opening end 411 and improve connection stability, in one embodiment, the connector 4 bends and extends at the opening end 411 to form a bent portion 413. It is understood that both the bent portion 413 and the opening end 411 are connected to one of the first diaphragm assembly 31 and the second diaphragm assembly 32. In this embodiment, the bent portion 413 is connected to the second diaphragm assembly 32.
[0065] In this embodiment, as Figures 2 to 5 , Figures 10 to 17 As shown, by bending the open end 411 to form a bent portion 413, the bent portion 413 can be connected to one of the first diaphragm assembly 31 and the second diaphragm assembly 32, thereby effectively increasing the connection area and improving connection stability. Optionally, the bent portion 413 extends along the plane of the first diaphragm assembly 31 or the second diaphragm assembly 32. It is understood that the surface of the bent portion 413 facing the first diaphragm assembly 31 or the second diaphragm assembly 32 is flush with the end face where the open end 411 is located, but this is not limited here.
[0066] Optionally, the magnetic circuit system 2 is provided with a clearance area 211 corresponding to the bend 413. It can be understood that by providing a clearance area 211 on the magnetic circuit system 2, the clearance area 211 can provide clearance for the bend 413, thereby saving the vibration space occupied by the thickness of the bend 413. Without affecting the performance of the magnetic circuit system 2, the thickness of the sound generating device 100 is reduced, which is beneficial for thin design.
[0067] To fully utilize the internal space of the connector 4, the connector 4 is provided with a first through hole. This arrangement can reduce weight. It is understood that the first through hole can connect to the first rear cavity 6; or, the first through hole can connect to the first front cavity 7. Optionally, the connector 4 is provided with a first through hole connecting to the first rear cavity 6. This arrangement can not only make full use of the internal space of the connector 4, but also reduce weight and improve the mid-frequency performance and sensitivity of the sound-generating device 100, which is not limited here.
[0068] It should be noted that the first through hole can be a hollow structure provided on the side wall of the connector 4, that is, the side wall of the connector 4 is hollow. Of course, in other embodiments, the first through hole can be a through hole or a notch, etc., and is not limited here.
[0069] In one embodiment, the sidewall of the connector 4 is provided with a recessed or protruding reinforcing portion extending circumferentially along the connector 4. It is understood that this increases the area of the upper and lower surfaces of the connector 4, facilitating the fixed connection between the connector 4 and the first diaphragm assembly 31, and between the connector 4 and the second diaphragm assembly 32. For example, when adhesive is used, the adhesive adheres to both the upper and lower surfaces of the connector 4; a larger adhesion area results in greater adhesive force.
[0070] In one embodiment, the connector 4 is a hollow cylindrical shape with openings at both ends. The connector 4 has a first end 421 and a second end 423. One of the first diaphragm assembly 31 and the second diaphragm assembly 32 is connected to the first end 421, and the other of the first diaphragm assembly 31 and the second diaphragm assembly 32 is connected to the second end 423.
[0071] In this embodiment, as Figure 18 and Figure 19 As shown, the connector 4 is a hollow cylindrical shape with open top and bottom. The connector 4 has a first end 421 and a second end 423, which are respectively connected to the first diaphragm assembly 31 and the second diaphragm assembly 32. It can be understood that by setting the connector 4 into a cylindrical structure, both the structural strength during transmission can be guaranteed, and energy loss can be reduced by reducing mass.
[0072] To further increase the connection area of the first end 421 and improve connection stability, in one embodiment, the first end 421 is folded to form a first flange 422. In this embodiment, as shown... Figure 19 As shown, the first flange 422 is formed by bending and extending the first end 421 along the plane of the first diaphragm assembly 31 or the second diaphragm assembly 32. It can be understood that the surface of the first flange 422 facing the first diaphragm assembly 31 or the second diaphragm assembly 32 is flush with the end face where the first end 421 is located, which is not limited here.
[0073] Similarly, to further increase the connection area of the second end 423 and improve connection stability, in one embodiment, the second end 423 is folded to form a second flange 424. In this embodiment, as... Figure 19As shown, the second flange 424 is formed by bending and extending the second end 423 along the plane of the first diaphragm assembly 31 or the second diaphragm assembly 32. It can be understood that the surface of the second flange 424 facing the first diaphragm assembly 31 or the second diaphragm assembly 32 is flush with the end face where the second end 423 is located, which is not limited here.
[0074] It should be noted that the first flange 422 is formed by bending and extending the first end 421 outward or inward, and the second flange 424 is formed by bending and extending the second end 423 outward or inward; no specific limitation is made here.
[0075] In one embodiment, the sidewall of the connector 4 is provided with a recessed or protruding reinforcing portion 425. In this embodiment, as... Figure 18 As shown, by providing a reinforcing part 425 on the side wall of the connector 4, the structural strength of the connector 4 can be strengthened, and the connection area between the first end 421 and the second end 423 of the connector 4 and the first diaphragm assembly 31 and the second diaphragm assembly 32 can be increased, thereby improving the connection stability.
[0076] To fully utilize the internal space of the connector 4, the connector 4 is provided with a second through hole. This arrangement can reduce weight. It is understood that the second through hole can connect to the first rear cavity 6; or, the second through hole can connect to the first front cavity 7. Optionally, the connector 4 is provided with a second through hole connecting to the first rear cavity 6. This arrangement can not only make full use of the internal space of the connector 4, but also reduce weight and improve the mid-frequency performance and sensitivity of the sound-generating device 100, which is not limited here.
[0077] It should be noted that the second through hole can be a hollow structure provided on the side wall of the connector 4, that is, the side wall of the connector 4 is hollow. Of course, in other embodiments, the second through hole can be a through hole or a notch, etc., and is not limited here.
[0078] In one embodiment, the connector 4 includes a first connecting portion 431, a second connecting portion 432, and a support portion 433 connected between the first connecting portion 431 and the second connecting portion 432. The first connecting portion 431 and the second connecting portion 432 are arranged opposite to each other along a first direction, and both the first connecting portion 431 and the second connecting portion 432 extend perpendicularly to the first direction and are elongated. One of the first diaphragm assembly 31 and the second diaphragm assembly 32 is connected to the first connecting portion 431, and the other of the first diaphragm assembly 31 and the second diaphragm assembly 32 is connected to the second connecting portion 432.
[0079] In this embodiment, as Figures 20 to 22 As shown, by setting the connector 4 into a bracket shape composed of rods, the space occupied is relatively small and the weight is also small.
[0080] Optionally, the support portion 433 extends along a first direction, and the support portion 433 includes one or more. When multiple support portions 433 are included, the multiple support portions 433 are arranged at intervals. In this embodiment, as... Figure 20 As shown, multiple support portions 433 are arranged at intervals along the length direction of the first connecting portion 431 or the second connecting portion 432.
[0081] Understandably, the first connecting part 431 and the second connecting part 432 extend laterally, and the support part 433 extends vertically. Multiple support parts 433, together with the first connecting part 431 and the second connecting part 432, form multiple roughly rectangular holes, which not only ensures transmission strength but also reduces mass. In addition, the connecting part 4 in this embodiment has a relatively regular shape and is easy to process and form.
[0082] In one embodiment, the support portion 433 includes a first segment 434 extending downward from one end of the first connecting portion 431, a second segment 435 extending from the lower end of the first segment 434 along the length direction of the first connecting portion 431 toward the other end of the first connecting portion 431, and a third segment 436 extending downward from the end of the second segment 435 away from the first segment 434 and connected to the second connecting portion 432. In this embodiment, as... Figure 21 As shown, the support part 433 extends in a linear bend, occupying minimal space.
[0083] In one implementation, such as Figure 22 As shown, the support portion 433 includes two parts, which are arranged at an angle and cross each other. Understandably, this arrangement allows the connector 4 to form a more stable structure with a smaller cross-section, thereby further reducing the space occupied.
[0084] It should be noted that, in order to reduce the weight of connector 4, connector 4 is made of a porous material. It can be understood that, by combining the porous material with a cylindrical or bracket-like structure, the mass of connector 4 can be further reduced.
[0085] In one embodiment, the first diaphragm assembly 31 includes a first diaphragm 311 and a first diaphragm plate 312 connected to the first diaphragm 311, and two voice coils 33 are both connected to the first diaphragm plate 312. The second diaphragm assembly 32 includes a second diaphragm 321 and a second diaphragm plate 322 connected to the second diaphragm 321.
[0086] Understandably, the periphery of the first diaphragm 311 is connected to the outer shell 1, and the two voice coils 33 are connected to the first diaphragm 312. In this embodiment, the first diaphragm 311 has a first folded ring. Optionally, the first diaphragm 311 includes a first folded ring, a first outer connecting portion disposed on the outside of the first folded ring, and a first inner connecting portion disposed on the inside of the first folded ring. The first outer connecting portion of the first diaphragm 311 can be connected to the outer shell 1, and the first inner connecting portion of the first diaphragm 311 is connected to the first diaphragm 312. It should be noted that the first folded ring of the first diaphragm 311 can be an upwardly convex bulge structure or a downwardly concave bulge structure.
[0087] Optionally, the first outer connecting portion, the first folded ring, and the first inner connecting portion of the first diaphragm 311 are integrally formed. In this embodiment, the first outer connecting portion of the first diaphragm 311 is connected to the first housing 11. To further increase the connection area between the first diaphragm 311 and the housing 1, and to improve the connection stability and sealing, the periphery of the first outer connecting portion of the first diaphragm 311 is bent and extended toward the outer wall of the first housing 11 to form a first extension, which is connected to the outer wall of the first housing 11.
[0088] Understandably, the periphery of the second diaphragm 321 is connected to the outer shell 1. In this embodiment, the second diaphragm 321 has a second folded ring. Optionally, the second diaphragm 321 includes a second folded ring, a second outer connecting portion disposed on the outside of the second folded ring, and a second inner connecting portion disposed on the inside of the second folded ring. The second outer connecting portion of the second diaphragm 321 can be connected to the outer shell 1, and the second inner connecting portion of the second diaphragm 321 is connected to the second vibrating plate 322. It should be noted that the second folded ring of the second diaphragm 321 can be an upwardly convex bulge structure or a downwardly concave bulge structure.
[0089] Optionally, the second outer connecting portion, the second folded ring, and the second inner connecting portion of the second diaphragm 321 are integrally formed. In this embodiment, the second outer connecting portion of the second diaphragm 321 is connected to the second housing 12. To further increase the connection area between the second diaphragm 321 and the housing 1, and improve the connection stability and sealing, the periphery of the second outer connecting portion of the second diaphragm 321 is bent and extended toward the outer wall of the second housing 12 to form a second extension, which is connected to the outer wall of the second housing 12.
[0090] In the above embodiments, such as Figures 2 to 5 , Figures 9 to 22 As shown, the connector 4 is separately configured from the first diaphragm assembly 31 and the second diaphragm assembly 32. Optionally, both ends of the connector 4 are bonded to the first diaphragm assembly 31 and the second diaphragm assembly 32, respectively.
[0091] Of course, in other embodiments, the connector 4 is integrally formed with the first diaphragm assembly 31 or the second diaphragm assembly 32, which is not limited here. Optionally, the connector 4 is integrally formed with the first vibrating plate 312 or the second vibrating plate 322.
[0092] In one embodiment, the first vibrating plate 312 is provided with a first protrusion extending toward the through hole 25. The first protrusion passes through the through hole 25 and is connected to the second diaphragm assembly 32. The first protrusion forms a connector 4.
[0093] In this embodiment, a first protrusion extending into the through hole 25 is provided on the first vibrating plate 312, allowing the first protrusion to pass through the through hole 25 and connect to the second diaphragm assembly 32, thus forming a connector 4 using the first protrusion. At this time, the first protrusion of the first vibrating plate 312 can form a connector 4 connecting the second diaphragm assembly 32, eliminating the need for an additional connector 4, thereby reducing the cost of the sound generating device 100.
[0094] In another embodiment, the second vibrating plate 322 is provided with a second protrusion extending toward the through hole 25. The second protrusion passes through the through hole 25 and is connected to the first diaphragm assembly 31. The second protrusion forms a connector 4.
[0095] In this embodiment, a second protrusion extending into the through hole 25 is provided on the second vibrating plate 322, allowing the second protrusion to pass through the through hole 25 and connect to the first diaphragm assembly 31, thus forming a connector 4. At this time, the second protrusion of the second vibrating plate 322 can form a connector 4 connecting the first diaphragm assembly 31, eliminating the need for an additional connector 4, thereby reducing the cost of the sound generating device 100.
[0096] Optionally, such as Figures 2 to 5 , Figure 9 As shown, the concave direction of the first fold ring is opposite to that of the second fold ring, and both are concave towards the direction close to the magnetic circuit system 2. Understandably, this arrangement effectively reduces the thickness and volume of the sound-generating device 100 along the first direction, achieving a thinner design.
[0097] In this embodiment, the connector 4 is formed by a first protrusion of the first vibrating plate 312 or a second protrusion of the second vibrating plate 322. The interior of the first or second protrusion can be a hollow structure. This structure can ensure the structural strength during transmission and reduce energy loss by reducing mass, thereby making the vibration transmitted by the connector 4 more significant and improving the high-frequency performance of the sound-generating device. The first and second protrusions have the same structure, which is convenient for processing and improves production efficiency, and is not limited here.
[0098] Understandably, in order to further increase the structural strength of the connector 4 and reduce its mass, in one embodiment, the connector 4 is tapered along the first direction. In this embodiment, as... Figure 10 , Figure 11 , Figure 13 , Figure 14 As shown, the area of the cross section of the connector 4 along the second direction gradually decreases or gradually increases along the first direction. This arrangement not only increases the structural strength of the connector 4 itself, but also improves the connection strength to ensure the driving force of the second diaphragm assembly 32.
[0099] It should be noted that the tapered connector 4 can also indirectly widen the distance between itself and the inner wall of the through hole 25, thereby providing effective clearance space for the diaphragm 5 and preventing interference between the diaphragm 5 and the connector 4 or the inner wall of the through hole 25.
[0100] Of course, the connector 4 may be tapered along the first direction, or the connector 4 may be tapered from both ends toward the middle along the first direction, or the connector 4 may not be tapered; this is not limited here.
[0101] Optionally, the cross-sectional shape of the sidewall of the connector 4 along the first direction is stepped, arc-shaped, or straight. In this embodiment, such as... Figures 2 to 5 , Figure 9 , Figure 12 As shown, the sidewall of the connector 4 has a stepped cross-sectional shape along the first direction, meaning the sidewall of the connector 4 is configured with multiple bends. This structure can further improve the strength of the connector 4 itself, and at the same time improve the connection strength of the connector 4, so as to obtain a better sound production effect. In one embodiment, the sidewall of the connector 4 has a stepped cross-sectional shape along the first direction, and the connector 4 has a clearance space to avoid the folded ring portion 52.
[0102] like Figure 13 As shown, the sidewall of the connector 4 has an arc-shaped cross-section along the first direction. In this embodiment, the arc-shaped sidewall can bulge towards the through hole 25 or be recessed away from the through hole 25. In both cases, the connector 4 has high structural strength, thereby achieving better connection strength.
[0103] In addition, such as Figure 14 As shown, the cross-sectional shape of the sidewall of the connector 4 along the first direction can also be a combination of stepped and arc shapes, which can further obtain higher structural strength and ensure the stability of the connection between the first diaphragm assembly 31 and the second diaphragm assembly 32.
[0104] Of course, such as Figure 10 and Figure 11As shown, the cross-sectional shape of the sidewall of the connector 4 along the first direction is straight, and is not limited here. It should be noted that the cross-sectional shape of the sidewall of the connector 4 along the first direction can be at least one of stepped, arc, and straight shapes or a combination thereof, and is not limited here.
[0105] In one embodiment, the sidewall of the connector 4 has a rectangular or circular cross-sectional shape along the second direction, or a combination of a circle and a rectangle, and the second direction is perpendicular to the first direction.
[0106] In this embodiment, as Figures 15 to 17 As shown, the projected shape of the connector 4 along the first direction is a rectangle, a circle, or a combination of a circle and a rectangle. It is understood that the cross-sectional shape of the connector 4 along the second direction is a rectangle, a circle, or a combination of a circle and a rectangle, and this is not limited here.
[0107] Understandably, the cross-sectional shape of the through hole 25 also includes circular and rectangular embodiments, which can match the connector 4, thereby allowing the connector 4 to be better accommodated and facilitating a fixed connection. When the cross-section of the connector 4 is circular, the cross-section of the through hole 25 is circular; when the cross-section of the connector 4 is rectangular, the cross-section of the through hole 25 is also rectangular, and these rectangles are all rounded rectangles with no sharp parts, improving the smoothness of the sound output of the sound-generating device 100 and the user's comfort.
[0108] In one embodiment, the connector 4 includes two skeletons 414 arranged along a first direction. The two skeletons 414 are respectively disposed on opposite sides of the diaphragm 5 along the first direction. One end of each skeleton 414 extends into the through hole 25 and is connected to the inner connecting part 54. The other ends of the two skeletons 414 are respectively connected to the first diaphragm assembly 31 and the second diaphragm assembly 32.
[0109] In this embodiment, as Figure 4 As shown, by setting the connector 4 as two skeletons 414 arranged along the first direction, the two skeletons 414 are respectively located on opposite sides of the diaphragm 5 along the first direction. In this way, the two skeletons 414 are connected to the first diaphragm assembly 31 and the second diaphragm assembly 32 respectively, so as to realize the linkage between the first diaphragm assembly 31 and the second diaphragm assembly 32, and reduce the length of the skeleton 414 in the first direction, thereby improving the structural strength and processing difficulty of the skeleton 414.
[0110] It should be noted that the structure of a single skeleton 414 can be similar to the structure of the connector 4 in the above embodiments, and is not limited here. Optionally, the two skeletons 414 are symmetrically arranged with respect to the inner connecting part 54. Of course, in other embodiments, the two skeletons 414 may also be asymmetrical. In this case, the structures of the two skeletons 414 may be exactly the same or different, and is not limited here.
[0111] In this embodiment, the diaphragm 5 can be a closed diaphragm or an annular diaphragm. As long as the diaphragm 5 and the connector 4 can cooperate to seal the through hole 25, thereby isolating the first rear cavity 6 and the first front cavity 7 from each other, there is no limitation here.
[0112] In one embodiment, the diaphragm 5 includes an inner connecting portion 54, a folded ring portion 52 surrounding the inner connecting portion 54, and an outer connecting portion 55 surrounding the folded ring portion 52. The outer connecting portion 55 is connected to the magnetic circuit system 2, and the inner connecting portion 54 is sandwiched between the connector 4 and the first diaphragm assembly 31 or the second diaphragm assembly 32.
[0113] In this embodiment, as Figures 2 to 5 , Figure 9 , Figure 23 and Figure 24 As shown, the diaphragm 5 can be a closed diaphragm. In this case, the inner connecting portion 54 of the diaphragm 5 is sandwiched between the connector 4 and the first diaphragm assembly 31 or the second diaphragm assembly 32, and the outer connecting portion 55 is connected to the magnetic circuit system 2, thereby completely sealing the through hole 25 using the diaphragm 5. It can be understood that at least part of the shape or outline of the inner connecting portion 54 of the diaphragm 5 is similar to the shape or outline of one end of the connector 4.
[0114] Understandably, the folded ring portion 52 of the diaphragm 5 can deform to ensure that the inner connecting portion 54 of the diaphragm 5 does not affect the connection relationship between the outer connecting portion 55 of the diaphragm 5 and the magnetic circuit system 2 when the connecting member 4 vibrates, thereby ensuring the sealing performance of the through hole 25.
[0115] It should be noted that the folded ring portion 52 of the diaphragm 5 can be an upwardly convex hull structure or a downwardly concave hull structure. The folded ring portion 52 of the diaphragm 5 is similar in structure or function to the first folded ring of the first diaphragm 311 and the second folded ring of the second diaphragm 321, and is not limited here.
[0116] In one embodiment, the outer connecting part 55 is connected to the side of the magnetic circuit system 2 near the first diaphragm assembly 31, and the inner connecting part 54 is sandwiched between the connector 4 and the first diaphragm assembly 31.
[0117] In another embodiment, the outer connecting part 55 is connected to the side of the magnetic circuit system 2 near the second diaphragm assembly 32, and the inner connecting part 54 is sandwiched between the connector 4 and the second diaphragm assembly 32.
[0118] Optionally, the outer connecting part 55 is connected to the side of the magnetic circuit system 2 near the second diaphragm assembly 32, and the inner connecting part 54 is sandwiched between the connector 4 and the second diaphragm assembly 32. The connector 4 is provided with a first through hole communicating with the first rear cavity 6.
[0119] When the diaphragm 5 is annular, in one embodiment, the diaphragm 5 includes an inner connecting portion 54, a folded ring portion 52 surrounding the inner connecting portion 54, and an outer connecting portion 55 surrounding the folded ring portion 52. The outer connecting portion 55 is connected to the magnetic circuit system 2. The inner connecting portion 54 is provided with an inner ring hole 541. The connector 4 passes through the inner ring hole 541 and the inner connecting portion 54 is connected to the outside of the connector 4 to close the through hole 25.
[0120] In this embodiment, as Figure 25 As shown, by setting the diaphragm 5 as an annular diaphragm, the processing cost of the diaphragm 5 can be effectively saved. A through hole structure, namely an inner annular hole 541, is formed in the center of the inner connecting part 54 of the diaphragm 5. The connector 4 passes through the inner annular hole 541 of the inner connecting part 54, and the inner connecting part 54 is connected to the outside of the connector 4. The outer connecting part 55 is connected to the magnetic circuit system 2 to close the through hole 25.
[0121] Understandably, the inner connecting portion 54 of the diaphragm 5 can be adjusted in shape according to the outer contour of the connector 4, as long as it can completely seal the through hole 25 with the connector 4, and is not limited here. In order to improve the connection strength and sealing performance between the inner connecting portion 54 of the diaphragm 5 and the outer wall of the connector 4, in one embodiment, a connecting platform is formed on the outer wall of the connector 4, and the inner connecting portion 54 is supported and connected to the connecting platform.
[0122] In one embodiment, the common magnetic part 26 includes a common magnet 261 and a common magnetic plate 262 stacked together, the common magnet 261 is connected to the magnetic yoke 21, and the through hole 25 passes through the common magnetic plate 262, the common magnet 261 and the magnetic yoke 21 in sequence; the side magnetic part 23 includes a side magnet 231 and a side magnetic plate 232 stacked together, the side magnet 231 is connected to the magnetic yoke 21; each central magnetic part 22 includes a central magnet 221 and a central magnetic plate 222 stacked together, the central magnet 221 is connected to the magnetic yoke 21.
[0123] Optionally, the common magnet 261, the side magnet 231, and the two central magnets 221 are all magnetized along the first direction, with the magnetization direction of the two central magnets 221 opposite to that of the common magnet 261 and the two side magnets 231. Understandably, this allows the two voice coils 33 to generate high driving forces within the two magnetic gaps 24, driving the movement of the first diaphragm assembly 31, which in turn drives the second diaphragm assembly 32 through the two connectors 4 within the two through holes 25, thus improving the performance of the sound-generating device 100.
[0124] In this embodiment, the common magnetic part 26 includes a common magnet 261 disposed on the magnetic yoke 21 and a common magnetic plate 262 disposed on the top of the common magnet 261. It is understood that the magnetic yoke 21 has a first inner hole, the common magnet 261 has a second inner hole corresponding to the first inner hole, and the common magnetic plate 262 has a third inner hole. The first inner hole, the second inner hole, and the third inner hole correspond one-to-one along a first direction and are interconnected to form a through hole 25.
[0125] Understandably, the through hole 25 directly connects the magnetic yoke 21, the common magnet 261, and the common magnetic plate 262. The linkage between the first diaphragm assembly 31 and the second diaphragm assembly 32 is achieved by using the connector 4 inside the through hole 25. This form is simple, and by setting the diaphragm 5 at the through hole 25, the first rear cavity 6 and the first front cavity 7 are isolated from each other, thereby avoiding mutual interference of sound wave airflow.
[0126] It should be noted that, in order to increase the linkage between the first diaphragm assembly 31 and the second diaphragm assembly 32, multiple through holes 25 are provided, and a connector 4 and a diaphragm 5 are provided for each through hole. That is, the through holes 25, connectors 4 and diaphragms 5 are provided in a one-to-one correspondence. Of course, the through holes 25 can be located in the center of the magnetic circuit system 2 or at the edge of the magnetic circuit system 2. That is, the through holes 25 can directly penetrate the magnetic yoke 21 and the side magnetic part 23 or the magnetic yoke 21 and the central magnetic part 22. There is no limitation here.
[0127] Understandably, the common magnetic part 26 can be formed by a common magnet 261 and a common magnetic conductive plate 262, with a through hole 25 provided in the center of the common magnetic part 26 by drilling or punching. Of course, the common magnetic part 26 can also be formed by multiple common magnets 261 and multiple common magnetic conductive plates 262, in which case the multiple common magnets 261 and multiple common magnetic conductive plates 262 surround to form the through hole 25, which is not limited here.
[0128] It should be noted that each central magnetic part 22 can be formed by a central magnet 221 and a central magnetic plate 222. Of course, in other embodiments, each central magnetic part 22 can also be formed by multiple central magnets 221 and multiple central magnetic plates 222, which is not limited here.
[0129] Understandably, the side magnetic portion 23 includes a baffle formed by bending the outer periphery of the self-conducting magnetic yoke 21, and the common magnetic portion 26 includes a baffle formed by bending the outer periphery of the self-conducting magnetic yoke 21. A magnetic gap 24 is formed between the central magnet 221 and the baffle. Alternatively, the side magnetic portion 23 includes a side magnet 231 disposed on the self-conducting magnetic yoke 21 and a side magnetic plate 232 disposed on the top of the side magnet 231, and the common magnetic portion 26 includes a common magnet 261 disposed on the self-conducting magnetic yoke 21 and a common magnetic plate 262 disposed on the top of the common magnet 261. The magnetic gap 24 is formed between the central magnet 221 and the side magnet 231 and the common magnet 261.
[0130] It should be noted that the side magnetic part 23 can be a ring structure, disposed on the outside of the two central magnetic parts 22 and the common magnetic part 26; or, the side magnetic part 23 includes multiple side magnetic parts 23, which are connected end to end to form a ring and disposed on the outside of the two central magnetic parts 22 and the common magnetic part 26; or, the multiple side magnetic parts 23 are spaced apart and surround the outside of the two central magnetic parts 22 and the common magnetic part 26, which is not limited here.
[0131] Optionally, two or four edge magnet portions 23 may be provided. In this embodiment, two or four edge magnets 231 forming the edge magnet portion 23 may be provided, and correspondingly, two or four edge magnetic guide plates 232 provided on the top of the edge magnets 231 may be provided; alternatively, when four edge magnets 231 are provided, the edge magnetic guide plates 232 may form a ring structure covering the top of the four edge magnets 231, which facilitates mass production.
[0132] In this embodiment, the common magnetic part 26 is abutted against, bonded to, or integrally formed with the edge magnetic part 23 at both ends along the third direction, and the first direction, the second direction, and the third direction are perpendicular to each other. It can be understood that the common magnetic part 26 can be separately provided from the edge magnetic part 23, or the common magnetic part 26 can be integrally formed with the edge magnetic part 23, and this is not limited here.
[0133] Optionally, the width of the common magnetic part 26 along the second direction is greater than or equal to 1.5 times the width of the central magnetic part 22 along the second direction. Understandably, this arrangement ensures both the space for the through hole 25 and the connector 4, and the magnetic field strength within the magnetic gap 24 formed by the central magnetic part 22 and the common magnetic part 26.
[0134] In order to facilitate the connection between the diaphragm 5 and the common magnetic part 26 without affecting the vibration of the first diaphragm assembly 31, in this embodiment, the magnetic circuit system 2 is provided with a first step part 263 corresponding to the external connection part 55.
[0135] In one embodiment, the common magnetic part 26 has a first stepped portion 263 surrounding the through hole 25 on one side of the opposite side of the guide yoke 21, and the external connecting part 55 is connected to the first stepped portion 263. In this embodiment, as... Figures 2 to 8 As shown, the common magnetic plate 262 has a first stepped portion 263 surrounding the through hole 25 on the side facing away from the common magnet 261, and the outer periphery of the diaphragm 5 is connected to the first stepped portion 263. It can be understood that the first stepped portion 263 is arranged around the through hole 25.
[0136] Of course, when the outer connecting portion 55 of the diaphragm 5 is connected to the magnetic yoke 21, in order to facilitate the connection between the diaphragm 5 and the magnetic yoke 21 and not affect the vibration of the second diaphragm assembly 32, in one embodiment, the magnetic yoke 21 has a second stepped portion around the through hole 25 on the side facing away from the common magnet 261, and the outer periphery of the diaphragm 5 is connected to the second stepped portion. The second stepped portion surrounds the through hole 25, which is not limited here.
[0137] In one implementation, such as Figures 2 to 4 As shown, a support platform 121 is provided adjacent to the first housing 11 in the second housing 12, and the periphery of the magnetic yoke 21 is supported and fixed to the support platform 121. This achieves stable fixation of the magnetic yoke 21, thereby providing stable support for the central magnetic part 22 and the peripheral magnetic part 23. In other embodiments, the second housing 12 may optionally be an injection molded part, with the second housing 12 and the magnetic yoke 21 integrally injection molded. It is understood that this arrangement improves the connection stability between the second housing 12 and the magnetic yoke 21.
[0138] Optionally, the side magnetic plate 232 of the side magnetic part 23 and the outer shell 1 are integrally injection molded or integrally molded, which is not limited here.
[0139] In one embodiment, the side magnet part 23 includes a side magnet 231 and a side magnetic plate 232 stacked together. The side magnet 231 is connected to the side of the magnetic yoke 21 facing away from the second diaphragm assembly 32. The first housing 11 is a metal part, and the first housing 11 and the side magnetic plate 232 are integrally formed.
[0140] In this embodiment, as Figures 2 to 8 As shown, the first housing 11 of the outer shell 1 can be a metal part. The first housing 11 and the side magnetic plate 232 are integrally formed by stretching and molding, which is not limited here. Of course, in other embodiments, when the first housing 11 of the outer shell 1 is an injection molded part, the first housing 11 and the side magnetic plate 232 are integrally injection molded, which is not limited here.
[0141] In one embodiment, the vibration system 3 further includes a centering support 34, which includes a first outer fixing part, a first inner fixing part, and a first elastic arm part connecting the first outer fixing part and the first inner fixing part. The first outer fixing part is connected to the outer shell 1, and the first inner fixing part is connected to the end of the voice coil 33 facing away from the first diaphragm assembly 31.
[0142] In this embodiment, as Figure 1 , Figure 2 , Figure 4 and Figure 5 As shown, by using the centering support 34 to center the voice coil 33, the voice coil 33 is prevented from being polarized or oscillating during vibration, thereby improving the operational stability of the first diaphragm assembly 31.
[0143] In one embodiment, the magnetic circuit system 2 has two long sides extending along a second direction and two short sides extending along a third direction. The centering support 34 includes two such supports, which are respectively arranged corresponding to the two short sides.
[0144] In this embodiment, as Figure 5 As shown, the centering support 34 can be selected as two, with the two centering supports 34 respectively located at both ends of the two short sides of the magnetic circuit system 2. This is not a limitation. Understandably, this arrangement effectively utilizes space and avoids interference between the centering support 34 and the magnetic circuit system 2.
[0145] like Figure 26 As shown, the present invention also proposes a sound-generating module 900, which includes the aforementioned sound-generating device 100. The specific structure of the sound-generating device 100 is as described in the foregoing embodiments. Since the sound-generating module 900 adopts all the technical solutions of all the foregoing embodiments, it has at least all the beneficial effects brought about by the technical solutions of the foregoing embodiments, which will not be described in detail here.
[0146] Understandably, the 900 sound module is used in electronic devices. These electronic devices can be mobile phones, headphones, smart wearable devices, smart glasses, etc., and are not limited here.
[0147] In one embodiment, the sound-generating module 900 further includes a module housing 800, which has a receiving cavity and a module sound hole 803 communicating with the receiving cavity. The sound-generating device 100 is disposed in the receiving cavity. A second front cavity 801 is formed between the module housing 800 and the first diaphragm assembly 31 of the sound-generating device 100, and a second rear cavity 802 is formed between the module housing 800 and the second diaphragm assembly 32 of the sound-generating device 100. The module sound hole 803 communicates with the second front cavity 801 and communicates with the first front cavity 7 of the sound-generating device 100 through the sound outlet 122 of the sound-generating device 100.
[0148] In this embodiment, as Figure 26 As shown, the module housing 800 of the sound-generating module 900 is used to install, fix, and protect the sound-generating device 100. It is understood that the magnetic circuit system 2 and vibration system 3 of the sound-generating device 100 can be directly installed in the module housing 800. Of course, the sound-generating device 100 can also be configured as an integrated modular structure installed in the module housing 800; this is not limited here.
[0149] Understandably, the sound-generating device 100 is installed in the module housing 800, so that a second front cavity 801 is formed between the module housing 800 and the first diaphragm assembly 31, and a second rear cavity 802 is formed between the module housing 800 and the second diaphragm assembly 32.
[0150] In this embodiment, the sound-generating device 100 is further provided with a sound outlet 122 communicating with the first front cavity 7, so that the sound waves radiated by the second diaphragm assembly 32 into the first front cavity 7 are radiated outward through the sound outlet 122. The module housing 800 is provided with a module sound hole 803 communicating with the second front cavity 801. The sound waves radiated by the first diaphragm assembly 31 into the second front cavity 801 are radiated outward through the module sound hole 803. At this time, the module sound hole 803 is communicating with the first front cavity 7 through the sound outlet 122, so that the sound waves radiated by the first diaphragm assembly 31 into the second front cavity 801 and the sound waves radiated by the second diaphragm assembly 32 into the first front cavity 7 are simultaneously radiated outward through the module sound hole 803, thus achieving sound wave superposition, thereby increasing the effective sound-generating area and improving the acoustic performance of the sound-generating module 900.
[0151] In one embodiment, the module housing 800 is further provided with a module vent 804 that communicates with the first rear cavity 6 and the second rear cavity 802 of the sound-generating device 100 respectively.
[0152] In this embodiment, as Figure 26 As shown, the module housing 800 is provided with a module vent 804 communicating with the second rear cavity 802. The module vent 804 is connected to the first rear cavity 6 through a vent 13. It can be understood that the acoustic airflow radiated by the first diaphragm assembly 31 to the first rear cavity 6 is radiated outward through the vent 13. The module housing 800 is provided with a module vent 804 communicating with the second rear cavity 802. The acoustic airflow radiated by the second diaphragm assembly 32 to the second rear cavity 802 is radiated outward through the module vent 804. At this time, the module vent 804 is connected to the first rear cavity 6 through the vent 13, so that the acoustic airflow radiated by the second diaphragm assembly 32 to the second rear cavity 802 and the acoustic airflow radiated by the first diaphragm assembly 31 to the first rear cavity 6 are simultaneously radiated outward through the module vent 804.
[0153] It is understandable that the module sound hole 803 and the module vent hole 804 on the module housing 800 can be disposed on different surfaces. The module sound hole 803 can be used to generate sound, and the module vent hole 804 can be used to release air. Of course, in other embodiments, the module sound hole 803 and the module vent hole 804 can also be used simultaneously to achieve noise reduction in the far field. For specific details, please refer to the prior art, which is not limited here.
[0154] In this embodiment, as Figure 26As shown, the module vent 804 includes multiple vent holes. Parts of the multiple module vent holes 804 form a first vent hole that communicates with the first rear cavity 6 through the vent port 13, and parts of the multiple module vent holes 804 form a second vent hole that communicates with the second rear cavity 802. Optionally, the first vent hole and the vent port 13 are directly opposite and communicate with each other, and the second vent hole communicates with the second rear cavity 802.
[0155] It should be noted that, in order to avoid the acoustic airflow radiated from the module vent 804 and the acoustic airflow radiated from the module acoustic hole 803 from interfering with each other, the module vent 804 and the module acoustic hole 803 are located on different surfaces or different sides of the module housing 800. That is, the first vent and the second vent are located on different surfaces or different sides of the module housing 800 from the module acoustic hole 803. This is not limited here.
[0156] The present invention also proposes an electronic device including the aforementioned sound-generating device 100. The specific structure of the sound-generating device 100 is as described in the foregoing embodiments. Since this electronic device adopts all the technical solutions of all the foregoing embodiments, it has at least all the beneficial effects brought about by the technical solutions of the foregoing embodiments, which will not be described in detail here.
[0157] In this embodiment, the electronic device further includes a device housing, and the sound-generating device 100 is disposed within the device housing. A second front cavity is formed between the first diaphragm assembly 31 of the sound-generating device 100 and the device housing, and a second rear cavity is formed between the second diaphragm assembly 32 of the sound-generating device 100 and the device housing. The device housing has a first sound hole communicating with the second front cavity, and the first sound hole communicates with the first front cavity 7 through a sound outlet 122. The device housing also has a second sound hole communicating with the second rear cavity, and the second sound hole communicates with the first rear cavity 6 through a vent 13.
[0158] Understandably, the first and second acoustic holes of the device housing can be located on different surfaces. The first acoustic hole can be used to generate sound, while the second acoustic hole can be used for venting. Of course, in other embodiments, the first and second acoustic holes can also be used simultaneously to achieve noise reduction in the far field. Specific details are provided in the prior art and are not limited here.
[0159] In this embodiment, the electronic device can be a mobile phone, earphones, smart wearable devices, etc., and is not limited thereto.
[0160] The present invention also proposes an electronic device comprising the aforementioned sound-emitting module 900. The specific structure of the sound-emitting module 900 is as described in the foregoing embodiments. Since this electronic device employs all the technical solutions of all the foregoing embodiments, it possesses at least all the beneficial effects brought about by the technical solutions of the foregoing embodiments, which will not be elaborated upon here.
[0161] In this embodiment, the electronic device also includes a device housing, and the sound-emitting module 900 is disposed within the device housing. It is understood that the electronic device can be a mobile phone, headphones, smart wearable devices, etc., and is not limited thereto.
[0162] The above description is merely an optional embodiment of the present invention and does not limit the patent scope of the present invention. Any equivalent structural transformations made under the concept of the present invention using the description and drawings of the present invention, or direct / indirect applications in other related technical fields, are included within the patent protection scope of the present invention.
Claims
1. A sound-generating device, characterized in that, The sound-generating device includes: A vibration system that vibrates along a first direction, the vibration system comprising a first diaphragm assembly, a second diaphragm assembly and two voice coils, the first diaphragm assembly and the second diaphragm assembly being spaced apart along the first direction, the two voice coils being parallel and spaced apart along a second direction and both being connected to the first diaphragm assembly, the first direction being perpendicular to the second direction; A magnetic circuit system is provided between the first diaphragm assembly and the second diaphragm assembly. The magnetic circuit system has two magnetic gaps and a through hole penetrating the magnetic circuit system. The through hole is located between the two magnetic gaps. Each voice coil is correspondingly provided with one magnetic gap. A connector, which passes through the through hole, and whose two ends are respectively connected to the first diaphragm assembly and the second diaphragm assembly; and A diaphragm, comprising an outer connecting portion, an inner connecting portion, and a folded ring portion located between the outer connecting portion and the inner connecting portion, wherein the outer connecting portion is connected to the magnetic circuit system and the inner connecting portion is connected to the connector to close the through hole; The first diaphragm assembly forms a first rear cavity with the magnetic circuit system and the diaphragm, the second diaphragm assembly forms a first front cavity with the magnetic circuit system and the diaphragm, and the sound-generating device is also provided with a sound outlet communicating with the first front cavity.
2. The sound-generating device as described in claim 1, characterized in that, The two ends of the connector are respectively bonded to the first diaphragm assembly and the second diaphragm assembly.
3. The sound-generating device as described in claim 2, characterized in that, The connector is a tube with one open end and one closed end. The connector has an open end and a closed end. The outer diameter of the open end is larger than the outer diameter of the closed end. The second diaphragm assembly is connected to the open end, and the first diaphragm assembly is connected to the closed end. Wherein, the connector bends and extends at the open end to form a bent portion, the bent portion being connected to the second diaphragm assembly; and / or, the magnetic circuit system has a clearance area corresponding to the bent portion; And / or, the connector is provided with a first through hole communicating with the first rear cavity; And / or, the connector is tapered along the first direction; or, the cross-sectional shape of the sidewall of the connector along the first direction is stepped, arc-shaped, or straight.
4. The sound-generating device as described in claim 2, characterized in that, The connector is a hollow cylinder with openings at both ends. The connector has a first end and a second end. One of the first diaphragm assembly and the second diaphragm assembly is connected to the first end, and the other of the first diaphragm assembly and the second diaphragm assembly is connected to the second end. Wherein, the first end is folded to form a first flange; and / or, the second end is folded to form a second flange; And / or, the sidewall of the connector is provided with a recessed or protruding reinforcing portion; And / or, the connector is provided with a second through hole communicating with the first rear cavity; And / or, the connector is tapered along the first direction; or, the cross-sectional shape of the sidewall of the connector along the first direction is stepped, arc-shaped, or straight.
5. The sound-generating device as described in claim 2, characterized in that, The connector includes a first connecting portion, a second connecting portion, and a support portion connected between the first connecting portion and the second connecting portion. The first connecting portion and the second connecting portion are arranged opposite to each other along the first direction, and both the first connecting portion and the second connecting portion extend perpendicularly to the first direction and are elongated. One of the first diaphragm assembly and the second diaphragm assembly is connected to the first connecting portion, and the other of the first diaphragm assembly and the second diaphragm assembly is connected to the second connecting portion. The support portion extends along the first direction; the support portion includes one or more, and the plurality of support portions are arranged at intervals. Alternatively, the support portion may include a first segment extending downward from one end of the first connecting portion, a second segment extending from the lower end of the first segment along the length direction of the first connecting portion toward the other end of the first connecting portion, and a third segment extending downward from the end of the second segment away from the first segment and connected to the second connecting portion. Alternatively, the support portion may include two portions, which are arranged at an angle and cross each other.
6. The sound-generating device as claimed in claim 1, characterized in that, The first diaphragm assembly includes a first diaphragm and a first diaphragm plate connected to the first diaphragm, and both voice coils are connected to the first diaphragm plate. The second diaphragm assembly includes a second diaphragm and a second diaphragm plate connected to the second diaphragm plate. The connecting member is integrally formed with the first diaphragm plate or the second diaphragm plate. The first vibrating plate has a first protrusion extending toward the through hole, the first protrusion passing through the through hole and connecting to the second diaphragm assembly, the first protrusion forming the connector; or, the second vibrating plate has a second protrusion extending toward the through hole, the second protrusion passing through the through hole and connecting to the first diaphragm assembly, the second protrusion forming the connector.
7. The sound-generating device as claimed in claim 1, characterized in that, The inner connecting portion is sandwiched between the connector and the first diaphragm assembly or the second diaphragm assembly; Alternatively, the inner connecting part is provided with an inner ring hole, the connector passes through the inner ring hole and the inner connecting part is connected to the outside of the connector to close the through hole; Alternatively, the connector may include two skeletons arranged along the first direction, with the two skeletons respectively disposed on opposite sides of the diaphragm along the first direction. One end of each skeleton extends into the through hole and is connected to the inner connecting portion, and the other end of each skeleton is respectively connected to the first diaphragm assembly and the second diaphragm assembly.
8. The sound-generating device as claimed in claim 1, characterized in that, The magnetic circuit system includes a magnetic yoke and a common magnetic part, a side magnetic part, and two central magnetic parts disposed on the side of the magnetic yoke facing the first diaphragm assembly. The two central magnetic parts are spaced apart along the second direction. The common magnetic part is located between the two central magnetic parts. The side magnetic part is located outside the common magnetic part and the two central magnetic parts. Each central magnetic part is spaced apart from the side magnetic part and the common magnetic part to form a magnetic gap. The through hole passes through the common magnetic part and the magnetic yoke in sequence.
9. The sound-generating device as described in claim 8, characterized in that, The common magnetic part includes a common magnet and a common magnetic plate stacked together. The common magnet is connected to the magnetic yoke. The through hole passes through the common magnetic plate, the common magnet and the magnetic yoke in sequence. The side magnetic part includes a side magnet and a side magnetic plate stacked together, and the side magnet is connected to the magnetic yoke; Each of the central magnetic units includes a central magnet and a central magnetic guide plate stacked together, wherein the central magnet is connected to the magnetic guide yoke; The common magnet, the side magnet, and the two center magnets are all magnetized along the first direction, and the magnetization direction of the two center magnets is opposite to that of the common magnet and the two side magnets.
10. The sound-generating device as claimed in claim 9, characterized in that, The common magnetic plate has a first stepped portion around the through hole on the side facing away from the common magnet, and the outer periphery of the diaphragm is connected to the first stepped portion; or, the magnetic yoke has a second stepped portion around the through hole on the side facing away from the common magnet, and the outer periphery of the diaphragm is connected to the second stepped portion. And / or, the two ends of the common magnetic part along the third direction are respectively abutted against the side magnetic part, bonded together, or integrally formed, and the first direction, the second direction, and the third direction are perpendicular to each other; And / or, the width of the common magnetic part along the second direction is greater than or equal to 1.5 times the width of the central magnetic part along the second direction.
11. The sound-generating device as claimed in claim 9, characterized in that, The sound-generating device also includes a housing, the housing having a mounting cavity, the magnetic circuit system being disposed within the mounting cavity, the periphery of the first diaphragm assembly being connected to one end of the housing, and the periphery of the second diaphragm assembly being connected to the other end of the housing; The first diaphragm assembly, the housing, the magnetic circuit system, and the diaphragm together form the first rear cavity, and the second diaphragm assembly, the housing, the magnetic circuit system, and the diaphragm together form the first front cavity. The housing is provided with the sound outlet.
12. The sound-generating device as claimed in claim 11, characterized in that, The outer casing is also provided with a vent that connects to the first rear cavity.
13. The sound-generating device as claimed in claim 12, characterized in that, The outer casing includes a first casing and a second casing arranged sequentially along the first direction. The magnetic circuit system is connected to the first casing and the second casing. The end of the first casing away from the second casing is connected to the periphery of the first diaphragm assembly. The end of the second casing away from the first casing is connected to the periphery of the second diaphragm assembly. The second casing is provided with the sound outlet. The vent is located in the first housing; or the vent is formed between the first housing and the second housing. And / or, the second housing is provided with a support platform adjacent to the first housing, and the periphery of the magnetic yoke is supported and fixed to the support platform; or, the second housing is an injection molded part, and the second housing and the magnetic yoke are integrally injection molded. And / or, the first housing is a metal part, and the first housing and the side magnetic plate are integrally formed; And / or, the sound outlet and the vent are located on different sides of the housing.
14. A sound-generating module, characterized in that, The sound-generating module includes: A module housing, the module housing having a receiving cavity and a module acoustic port communicating with the receiving cavity; and The sound-generating device as described in any one of claims 1 to 13, wherein the sound-generating device is disposed within the accommodating cavity, a second front cavity is formed between the module housing and the first diaphragm assembly of the sound-generating device, and a second rear cavity is formed between the module housing and the second diaphragm assembly of the sound-generating device; The module's sound hole is connected to the second front cavity, and is connected to the first front cavity of the sound-generating device through the sound outlet of the sound-generating device.
15. The sound-generating module as described in claim 14, characterized in that, The module housing is also provided with module vent holes that communicate with the first rear cavity and the second rear cavity of the sound-generating device, respectively.
16. An electronic device, characterized in that, The electronic device includes a sound-generating device as described in any one of claims 1 to 13; Alternatively, the electronic device may include the sound-generating module as described in claim 14 or 15.