CN118102186A - Sounding monomer, sounding module and electronic product - Google Patents

Abstract

The invention discloses a sounding unit, which comprises a first sounding unit, a second sounding unit and a magnetic circuit system, wherein the first sounding unit comprises an annular first vibrating diaphragm and a first voice coil connected with the first vibrating diaphragm; the magnetic circuit system comprises a central magnetic circuit and a side magnetic circuit positioned at the periphery of the central magnetic circuit, a first magnetic gap is formed between the central magnetic circuit and the side magnetic circuit, and one side of the first voice coil, which is far away from the first vibrating diaphragm, is inserted into the first magnetic gap; the central magnetic circuit is provided with a second magnetic gap, the second voice coil is a flat voice coil, the axis of the second voice coil extends along a second direction perpendicular to the first direction, and one side of the second voice coil, which is far away from the second vibrating diaphragm, is inserted into the second magnetic gap. The sounding single body integrates the high-low sound sounding modules, ensures that the middle-low sound performance is not reduced, effectively improves the high-frequency performance, and widens the sounding frequency band.

Description

Sounding monomer, sounding module and electronic product

Technical Field

The invention relates to the electroacoustic field, in particular to a sounding monomer, a sounding module and an electronic product.

Background

The micro-speaker is widely applied to modern portable, communication and intelligent devices due to the small size, and the requirements of users on high sound quality are increasing, especially for some portable intelligent devices, the users are not satisfied with the presence or absence of sound, but more pursue good sound quality.

A complete micro sounding module consists of micro sounding monomers, front and rear sound cavities and the like; when the micro-speaker works, the front sound cavity is subjected to low-pass filtering, and when the frequency of a driving signal is larger than the resonance frequency (Fh) of the front sound cavity, the loudness of the speaker is greatly reduced. At present, the front cavity resonance point of the miniature sound generating module in the intelligent mobile terminal is mostly smaller than 6000Hz, so that the effective frequency band of the miniature loudspeaker is narrowed, the tone quality is monotonous, and the tone quality is poor.

Disclosure of Invention

The invention aims to provide a sounding monomer which can effectively improve the high-frequency performance and widen the sounding frequency band while ensuring that the middle and low sound performance is not reduced.

In order to achieve the above and other objects, the present invention provides a sound generating unit, including a first sound generating unit, a second sound generating unit, and a magnetic circuit, where the first sound generating unit includes a first annular diaphragm and a first voice coil connected to the first diaphragm, the second sound generating unit includes a second diaphragm and a second voice coil connected to the second diaphragm, the second diaphragm is located at an inner periphery of the first diaphragm, the first diaphragm and the second diaphragm are coaxially arranged, and the first voice coil and the second voice coil vibrate along a first direction;

the magnetic circuit system comprises a central magnetic circuit and a side magnetic circuit which is positioned at the periphery of the central magnetic circuit, wherein the central magnetic circuit and the side magnetic circuit are arranged at intervals, a first magnetic gap is formed between the central magnetic circuit and the side magnetic circuit, and one side of the first voice coil, which is far away from the first vibrating diaphragm, is inserted into the first magnetic gap;

The central magnetic circuit is provided with a second magnetic gap, the second voice coil is a flat voice coil, the axis of the second voice coil extends along a second direction perpendicular to the first direction, and one side, away from the second vibrating diaphragm, of the second voice coil is inserted into the second magnetic gap.

Optionally, the central magnetic circuit has a through hole forming the second magnetic gap.

Optionally, the central magnetic circuit has first magnetic component, second magnetic component, third magnetic component and fourth magnetic component, first magnetic component, second magnetic component, third magnetic component and fourth magnetic component enclose and close and form the through-hole, along the second direction, first magnetic component and second magnetic component are located the both sides of second voice coil, along the third direction perpendicular to respectively first direction with the second direction, third magnetic component and fourth magnetic component are located the both sides of second voice coil.

Optionally, the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component are independent structures;

Or the first magnetic component and the third magnetic component are integrally formed, and the second magnetic component and the fourth magnetic component are integrally formed;

Or the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component are integrally formed.

Optionally, the central magnetic circuit includes a first magnetic conductive plate, a first magnet, a second magnetic conductive plate, and a second magnet sequentially stacked along the first direction, and the second diaphragm is disposed opposite to the first magnetic conductive plate.

Optionally, the first magnetic conductive plate, the first magnet, the second magnetic conductive plate, and the second magnet collectively define the second magnetic gap;

Or the first magnetic conduction plate, the first magnet and the second magnetic conduction plate jointly define the second magnetic gap, and the second magnetic gap is positioned on one side of the second magnet, which is close to the second vibrating diaphragm.

Optionally, the central magnetic circuit includes a first magnet, a second magnetic conductive plate, and a second magnet sequentially stacked along the first direction, and the second diaphragm is disposed opposite to the first magnet.

Optionally, the first magnet, the second magnetically permeable plate, and the second magnet collectively define the second magnetic gap;

or the first magnet and the second magnetic conduction plate jointly define the second magnetic gap, and the second magnetic gap is positioned at one side of the second magnet close to the second vibrating diaphragm.

Optionally, the first magnet includes a first magnet, a second magnet and a third magnet magnetized along the first direction, the second magnet and the third magnet are located at one side of the second voice coil along the second direction, the first magnet is located at the other side of the second voice coil, and the third magnet is located at one side of the second magnet away from the first magnet; the magnetizing direction of the first magnet is opposite to the magnetizing direction of the second magnet and the same as the magnetizing direction of the third magnet;

the second magnet comprises a fourth magnet and a fifth magnet which are magnetized along the first direction and have the same magnetizing direction, the fourth magnet and the fifth magnet are respectively positioned at two sides of the second voice coil along the second direction, and the magnetizing directions of the first magnet and the fourth magnet are opposite.

Optionally, the first vibrating diaphragm includes annular first reinforcement portion, annular first ring and annular second ring, the outer periphery and the inner periphery of first reinforcement portion connect respectively in first ring inner periphery with the outer periphery of second ring, first voice coil loudspeaker voice coil connect in first reinforcement portion be close to one side of first magnetic gap.

Optionally, the second vibrating diaphragm includes a second reinforcing portion and a third ring, the second voice coil is connected to a side of the second reinforcing portion, which is close to the second magnetic gap, and the second reinforcing portion is connected to an inner periphery of the third ring;

or the second vibrating diaphragm is a plane vibrating diaphragm;

or the second vibrating diaphragm comprises a planar vibrating diaphragm and a second reinforcing part fixed on the planar vibrating diaphragm.

In order to achieve the above and other objects, the present invention further provides a sound module, which includes a housing and the sound unit located in the housing.

In order to achieve the above and other objects, the present invention further provides an electronic product, which includes the above sounding module; or, the electronic product comprises the sounding monomer.

The sound generating unit comprises a first sound generating unit, a second sound generating unit and a magnetic circuit system, wherein the first sound generating unit comprises an annular first vibrating diaphragm and a first voice coil connected with the first vibrating diaphragm, the second sound generating unit comprises a second vibrating diaphragm and a second voice coil connected with the second vibrating diaphragm, the second vibrating diaphragm is positioned at the inner periphery of the first vibrating diaphragm, the first vibrating diaphragm and the second vibrating diaphragm are coaxially arranged, and the first voice coil and the second voice coil vibrate along a first direction; the magnetic circuit system comprises a central magnetic circuit and a side magnetic circuit which is positioned at the periphery of the central magnetic circuit, wherein the central magnetic circuit and the side magnetic circuit are arranged at intervals, a first magnetic gap is formed between the central magnetic circuit and the side magnetic circuit, and one side of the first voice coil, which is far away from the first vibrating diaphragm, is inserted into the first magnetic gap; the central magnetic circuit is provided with a second magnetic gap, the second voice coil is a flat voice coil, the axis of the second voice coil extends along a second direction perpendicular to the first direction, and one side, away from the second vibrating diaphragm, of the second voice coil is inserted into the second magnetic gap. The first sound generating unit is a bass unit, the second sound generating unit is a treble unit, the treble sound generating modules and the bass sound generating modules are integrated together, the middle bass performance is not reduced, the high-frequency performance is effectively improved, and the sound generating frequency band is widened; in addition, the second voice coil is a flat voice coil, and is inserted into the second magnetic gap in the central magnetic circuit, so that the driving force is effectively improved, the acoustic performance is further improved, and the volume of a product can be effectively reduced by the flat voice coil.

In order to make the above objects, features and advantages of the present invention more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a block diagram of a sounding monomer according to an embodiment of the present invention.

Fig. 2 is a bottom structure diagram of a sounding monomer according to an embodiment of the present invention.

Fig. 3 is a simplified exploded view of a sound emitting unit according to an embodiment of the present invention.

Fig. 4 is a detailed exploded view of a sounding monomer according to an embodiment of the present invention.

Fig. 5 is a cross-sectional view of a sounding monomer according to an embodiment of the present invention.

Fig. 6 is a cross-sectional view of a sound producing monomer forward placement provided by an embodiment of the present invention.

Fig. 7 is a cross-sectional view of a magnetic circuit system and a second voice coil of a sounding monomer according to an embodiment of the present invention.

Fig. 8 is a cross-sectional view of a sound emitting unit according to another embodiment of the present invention.

Fig. 9 is a top view of a magnetic circuit system of a sounding monomer according to an embodiment of the present invention.

Fig. 10 is a top view of a center magnetic circuit and a second voice coil of a sounding unit according to an embodiment of the present invention.

Fig. 11 is a structural diagram of a first magnet of a sounding unit according to an embodiment of the present invention.

Fig. 12 is a top view of a first magnet of a sound-emitting unit according to another embodiment of the present invention.

Fig. 13 is an exploded view of a magnetic circuit system of a sounding monomer according to an embodiment of the present invention.

Fig. 14 is an exploded view of a magnetic circuit system of a sounding unit according to another embodiment of the present invention.

Fig. 15 is a bottom structure diagram of a central magnetic circuit and an injection molding part of a sounding monomer according to an embodiment of the present invention.

Fig. 16 is an exploded view of a second voice coil electrical connection structure of a sounding unit according to an embodiment of the present invention.

Fig. 17 is a cross-sectional view of a sound emitting unit provided in an embodiment of the present invention.

Fig. 18 is an exploded view of the second diaphragm, the first magnetic conductive plate and the injection molding part of the sounding monomer according to the embodiment of the present invention.

Fig. 19 is a cross-sectional view of a magnetic circuit system and a second voice coil of a sounding monomer according to another embodiment of the present invention.

Fig. 20 is a cross-sectional view of a sound module according to an embodiment of the present invention.

Reference numerals illustrate:

10 is a first sound generating unit, 11 is a first reinforcing part, 12 is a first folding ring, 121 is a first inner fixing part, 122 is a first outer fixing part, 13 is a second folding ring, 131 is a second inner fixing part, 132 is a second outer fixing part, 14 is a first voice coil, 15 is a centering support piece, 20 is a second sound generating unit, 200 is a planar vibrating diaphragm, 21 is a second reinforcing part, 22 is a third folding ring, 221 is a third inner fixing part, 222 is a third outer fixing part, 23 is a second voice coil, 231 is a lead wire, 24 is an injection molding part, 241 is an electric connecting piece, 2411 is a welding part, 25 is a fixing ring, 30 is a magnetic circuit system, 31 is a central magnetic circuit, 311 is a first magnetic conductive plate, 3111 is an opening, 3112 is a protruding ring, 3113 is a concave portion, 312 is a first magnet, 3121 is a first magnet, 3122 is a second magnet, 3123 is a third magnet, 3124 is a sixth magnet, 3125 is a seventh magnet, 3127 is a unfilled corner, 313 is a second magnetic conductive plate, 314 is a second magnet, 3141 is a fourth magnet, 3142 is a fifth magnet, 3143 is an eighth magnet, 3144 is a ninth magnet, 315 is an avoiding portion, 316 is an avoiding portion, 32 is a side magnetic circuit, 321 is a side magnetic conductive plate, 322 is a side magnet, 33 is a yoke, 331 is a limiting hole, 332 is a groove, 40 is a housing, 50 is a circuit board, 51 is a weldment, and 60 is a casing.

Detailed Description

Various exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless it is specifically stated otherwise.

The following description of at least one exemplary embodiment is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.

Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of exemplary embodiments may have different values.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

As shown in fig. 1-7, the present invention proposes a sounding unit, which includes a first sounding unit 10, a second sounding unit 20 and a magnetic circuit system 30, where the first sounding unit 10 includes an annular first diaphragm and a first voice coil 14 connected to the first diaphragm, the second sounding unit 20 includes a second diaphragm and a second voice coil 23 connected to the second diaphragm, the second diaphragm is located at an inner periphery of the first diaphragm, and the first voice coil 14 and the second voice coil 23 vibrate along a first direction, which may be a vertical direction; the magnetic circuit system 30 comprises a central magnetic circuit 31 and a side magnetic circuit 32 positioned at the periphery of the central magnetic circuit 31, wherein the central magnetic circuit 31 and the side magnetic circuit 32 are arranged at intervals, a first magnetic gap is formed between the central magnetic circuit 31 and the side magnetic circuit 32, and one side of the first voice coil 14 away from the first vibrating diaphragm is inserted into the first magnetic gap; the center magnetic circuit 31 has a second magnetic gap, the second voice coil 23 is a flat voice coil and an axis extends in a second direction perpendicular to the first direction, and a side of the second voice coil 23 remote from the second diaphragm is inserted into the second magnetic gap. The first diaphragm and the second diaphragm are coaxially arranged, the first sound generating unit 10 may be a bass unit, and the second sound generating unit 20 may be a treble unit.

According to the sounding unit, the magnetic gaps corresponding to the high-pitch unit and the low-pitch unit are limited by adopting the set of magnetic circuit system, namely, the high-pitch unit and the low-pitch unit are integrated together, so that the sounding unit is compact in structure, the middle-low-pitch performance is not reduced, the high-frequency performance is effectively improved, and the sounding frequency band is widened; in addition, the second voice coil 23 is a flat voice coil, and is inserted into the second magnetic gap inside the central magnetic circuit 31, so that the driving force is effectively improved, the acoustic performance is further improved, the product volume can be effectively reduced by the flat voice coil, and the product is thin and light in weight.

In one embodiment, as shown in fig. 10, the central magnetic circuit 31 has a through hole that forms the second magnetic gap. The second magnetic gap is designed by adopting a through hole so that the flat second voice coil 23 is convenient to insert, and magnetic circuits are arranged on two sides of the second voice coil 23, so that higher magnetic field intensity can be provided for the second voice coil 23.

Further, as shown in fig. 6, the central magnetic circuit 31 has a first magnetic component, a second magnetic component, a third magnetic component and a fourth magnetic component, where the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component enclose to form the through hole, and the first magnetic component and the second magnetic component are located at two sides of the second voice coil 23 along the second direction, for example, the second direction may be a horizontal short side direction, and the third magnetic component and the fourth magnetic component are located at two sides of the second voice coil 23 along a third direction perpendicular to the first direction and the second direction, for example, the third direction may be a horizontal long side direction. The four magnetic components comprise magnets, and the magnets can be one or two or even more, and the two or even more magnets are arranged along the first direction; the magnetic assembly further includes a magnetic conductive plate interposed between adjacent two of the magnets to guide magnetic lines of force more intensively through the second voice coil 23.

Further, the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component are of independent structures, namely the magnetic components are independent relatively and assembled flexibly; or the first magnetic component and the third magnetic component are integrally formed, the second magnetic component and the fourth magnetic component are integrally formed, for example, two magnetic components are combined into an L shape (the two magnetic components are vertically distributed), and two L-shaped structures are enclosed to form a through hole, so that the assembly complexity is reduced, and the assembly precision and the assembly speed are improved; or the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component are integrally formed, so that the assembly precision and the assembly speed can be further improved, and the assembly efficiency is improved.

In another embodiment, the central magnetic circuit 31 includes two magnetic components, which are spaced apart to form the second magnetic gap, and are disposed on both sides of the second voice coil 23 along the second direction. Thus, magnetic components on two sides of the second voice coil 23 along the third direction can be saved, the cost is reduced, and the structure is simpler.

In one embodiment, as shown in fig. 6, the central magnetic circuit 31 includes a first magnetic conductive plate 311, a first magnet 312, a second magnetic conductive plate 313, and a second magnet 314 sequentially stacked along the first direction, the second diaphragm is disposed opposite to the first magnetic conductive plate 311, a second magnetic gap is disposed in the middle of the central magnetic circuit 31, and a side of the second voice coil 23 away from the second diaphragm is inserted into the second magnetic gap. Specifically, the first magnetic conductive plate 311, the first magnet 312, the second magnetic conductive plate 313, and the second magnet 314 together define the second magnetic gap, that is, the first magnetic conductive plate 311, the first magnet 312, the second magnetic conductive plate 313, and the second magnet 314 sequentially penetrate to form the second magnetic gap, so that a larger vibration space can be obtained;

or as shown in fig. 19, the first magnetic conductive plate 311, the first magnet 312 and the second magnetic conductive plate 313 together define the second magnetic gap, and the second magnetic gap is located at a side of the second magnet 314 close to the second diaphragm, that is, the first magnetic conductive plate 311, the first magnet 312 and the second magnetic conductive plate 313 sequentially penetrate to form the second magnetic gap, the second magnet 314 covers the second magnetic gap, and no gap is required to be left between the second magnet 314, so that the assembly is convenient. The gap of the first magnetic conductive plate 311 forms an upper magnetic gap, the gap of the second magnetic conductive plate 313 forms a lower magnetic gap, the second voice coil 23 has an upper driving edge and a lower driving edge, the upper driving edge is located in the upper magnetic gap, the lower driving edge is located in the lower magnetic gap, and the central magnetic circuit 31 drives the upper driving edge and the lower driving edge of the second voice coil 23 simultaneously, so that stronger driving force can be obtained, and the acoustic performance of the product is improved.

In a specific example, the second diaphragm is located above the first magnetic conductive plate 311, a fixing ring 25 is disposed above the edge of the first magnetic conductive plate 311, the second diaphragm is located on the fixing ring 25, the distance between the second diaphragm and the first magnetic conductive plate 311 is enlarged by the fixing ring 25, a deformation space is provided for the downward vibration of the second diaphragm, and the outer side edge of the fixing ring 25 is aligned with the outer side edge of the first magnetic conductive plate 311, so that the assembly is convenient; in another example, the edge of the first magnetic conductive plate 311 protrudes upward to form a protruding ring 3112, the second diaphragm is fixed on the protruding ring 3112, the protruding ring 3112 also provides a deformation space for the second diaphragm to vibrate downward, the protruding ring 3112 is a part of the first magnetic conductive plate 311, the installation of the fixing ring 25 is omitted, and the assembly accuracy and efficiency are improved.

In another embodiment, as shown in fig. 8, the central magnetic circuit 31 includes a first magnet 312, a second magnetic conductive plate 313, and a second magnet 314 stacked in this order along the first direction, and a second diaphragm is disposed opposite to the first magnet 312. A gap is formed in the middle of the central magnetic circuit 31, and one side of the second voice coil 23, which is far away from the second diaphragm, is inserted into the gap. Namely, the first magnet 312, the second magnetic conductive plate 313 and the second magnet 314 together define the second magnetic gap, that is, the first magnet 312, the second magnetic conductive plate 313 and the second magnet 314 sequentially penetrate to form the second magnetic gap, so that a larger vibration space can be obtained; or the first magnet 312 and the second magnetic conductive plate 313 together define the second magnetic gap, and the second magnetic gap is located at one side of the second magnet 314 near the second diaphragm, that is, the first magnet 312 and the second magnetic conductive plate 313 sequentially penetrate to form the second magnetic gap, the second magnet 314 covers the second magnetic gap, and no gap is required to be left on the second magnet 314, so that the assembly is convenient. The gap of the first magnet 312 forms an upper magnetic gap, the gap of the second magnetic conductive plate 313 forms a lower magnetic gap, the second voice coil 23 has an upper driving edge and a lower driving edge, the upper driving edge is located in the upper magnetic gap, the lower driving edge is located in the lower magnetic gap, and the central magnetic circuit 31 drives the upper driving edge and the lower driving edge of the second voice coil 23 simultaneously, so that stronger driving force can be obtained, and the acoustic performance of the product is improved.

In a specific example, the second diaphragm is located above the first magnet 312, a fixing ring 25 is disposed between the second diaphragm and the first magnet 312, the outer periphery of the second diaphragm is fixed on the fixing ring 25, the inner periphery of the first diaphragm is fixed between the first magnet 312 and the fixing ring 25, and the distance between the second diaphragm and the first magnetic conductive plate 311 is enlarged by the fixing ring 25, so as to provide a deformation space for the downward vibration of the second diaphragm. In this embodiment, the first magnetic conductive plate 311 is not disposed above the first magnet 312, so that the thickness of the product can be further reduced.

Further, as shown in fig. 7, the first magnet 312 includes a first magnet 3121, a second magnet 3122 and a third magnet 3123 magnetized along the first direction, the second magnet 3122 and the third magnet 3123 are located at one side of the second voice coil 23 along the second direction, the first magnet 3121 is located at the other side of the second voice coil 23, and the third magnet 3123 is located at one side of the second magnet 3122 away from the first magnet 3121; the magnetization direction of the first magnet 3121 is opposite to the magnetization direction of the second magnet 3122 and the same as the magnetization direction of the third magnet 3123. The second magnet 314 includes a fourth magnet 3141 and a fifth magnet 3142 magnetized in the first direction and the same magnetizing direction, and the fourth magnet 3141 and the fifth magnet 3142 are respectively located at two sides of the second voice coil 23 in the second direction, and the first magnet 3121 is magnetized in the opposite direction to the fourth magnet 3141.

The side magnetic circuit 32 includes a side magnet 322 and a side magnetic plate 321 above the side magnet 322, the side magnetic plate 321 and the second magnetic plate 313 are spaced apart to form a first magnetic gap, the first voice coil 14 is at least partially inserted into the first magnetic gap, and the magnetizing direction of the side magnet 322 is parallel and opposite to the magnetizing direction of the fourth magnet 3141. The magnetic circuit system 30 further includes a magnetic yoke 33, and the central magnetic circuit 31 and the side magnetic circuits 32 are fixed on the same side of the magnetic yoke 33 to guide magnetic force lines and avoid magnetic leakage.

Taking the magnetizing direction in fig. 7 as an example, the N poles of the first magnet 3121 and the third magnet 3123 are downward, the N poles of the second magnet 3122, the fourth magnet 3141 and the fifth magnet 3142 are upward, partial magnetic lines of force of the first magnet 3121 and the fourth magnet 3141 pass through the lower driving side of the second voice coil via the left second magnetic conduction plate 313, pass through the right second magnetic conduction plate 313 to the second magnet 3122, pass through the upper driving side of the second voice coil from the second magnet 3122 to the first magnet 3121 (if the first magnetic conduction plate 311 is provided, the magnetic lines of force emitted from the second magnet 3122 pass through the right first magnetic conduction plate 311 and pass through the upper driving side to the first magnet 3121 again via the left first magnetic conduction plate 311), and the upper driving side of the second voice coil 23 is opposite to the current direction of the lower driving side, so that the stress directions of the upper driving side and the lower driving side are the same, the resultant force is maximum, and the driving force is large. Part of magnetic force lines of the fourth magnet 3141 and the first magnet 3121 pass through the first voice coil 14 via the left second magnetic conduction plate 313, then pass through the left magnetic conduction plate 321 to the left magnet 322, and return to the fourth magnet 3141 via the yoke 33, thus forming a magnetic circuit; the magnetic lines of force of the third magnet 3123 and the fifth magnet 3142 pass through the first voice coil 14 via the right second magnetic conductive plate 313, are transferred to the right magnet 322 via the right magnetic conductive plate 321, and return to the fifth magnet 3142 via the yoke 33, thereby forming a magnetic circuit. The magnets are arranged on the upper side and the lower side of the central magnetic circuit part and the second magnetic conduction plate 313, so that more and denser magnetic force lines reach the first voice coil 14 through the second magnetic conduction plate 313, and the driving force is larger, and the magnetic field strength and the driving force can be improved by arranging the side magnetic circuit 32.

Further, as shown in fig. 11, the first magnet 312 further includes a sixth magnet 3124 and a seventh magnet 3125, the sixth magnet 3124 and the seventh magnet 3125 are distributed on two sides of the second voice coil 23 along the third direction, the first magnet 3121, the seventh magnet 3125, the third magnet 3123 and the sixth magnet 3124 are connected end to end, and the second magnet 3122 is added to form a through hole together for inserting the second voice coil 23.

Similarly, as shown in fig. 13, the second magnet 314 further includes an eighth magnet 3143 and a ninth magnet 3144, where the eighth magnet 3143 and the ninth magnet 3144 are distributed on two sides of the second voice coil 23 along the third direction, and the fourth magnet 3141, the ninth magnet 3144, the fifth magnet 3142 and the eighth magnet 3143 are surrounded end to form a through hole, so that the magnetic field strength of the first magnetic gap can be further improved by the eighth magnet 3143 and the ninth magnet 3144. The side magnets 322 have 4 pieces, which are respectively disposed around the second magnet 314, and in other embodiments, the side magnets 322 are in a ring-shaped integrated structure, so that the assembly is convenient.

The first magnet 3121 and the fourth magnet 3141 constitute the first magnetic assembly described above, the second magnet 3122, the third magnet 3123, and the fifth magnet 3142 constitute the second magnetic assembly described above, the sixth magnet 3124 and the eighth magnet 3143 constitute the third magnetic assembly, and the seventh magnet 3125 and the ninth magnet 3144 constitute the fourth magnetic assembly.

The second magnetic conductive plate 313 may be a split structure, and corresponds to the first magnetic component, the second magnetic component, the third magnetic component, and the fourth magnetic component, respectively; as shown in fig. 13 and 14, the second magnetic conductive plate 313 may be integrally formed, which is convenient for assembly.

In one embodiment, as shown in fig. 14, the first magnet 3121, the third magnet 3123, the sixth magnet 3124, and the seventh magnet 3125 of the first magnet 312 are a ring-shaped integrated structure, or the first magnet 312 is an integrated structure as a whole; the second magnet 314 is integrally formed, so that the assembly is convenient and the assembly precision is higher. In another embodiment, the first magnet 3121 and the sixth magnet 3124 of the first magnet 312 are integrally formed, the third magnet 3123 and the seventh magnet 3125 are integrally formed, or the third magnet 3123, the second magnet 3122 and the seventh magnet 3125 are integrally formed; similarly, the fourth magnet 3141 and the eighth magnet 3143 are integrally formed, and the fifth magnet 3142 and the ninth magnet 3144 are integrally formed. In still another embodiment, as shown in fig. 13, the first magnet 3121, the second magnet 3122, the third magnet 3123, the sixth magnet 3124 and the seventh magnet 3125 of the first magnet 312 are separately assembled, or the first magnet 3121, the third magnet 3123, the sixth magnet 3124 and the seventh magnet 3125 are separately assembled, and the second magnet 3122 and the third magnet 3123 are integrally assembled. Namely the split, unitary structural description of the first, second, third and fourth magnetic assemblies described above.

The sounding monomer of the invention also comprises a shell 40, the shell 40 is fixed with the side magnetic conductive plate 321, the outer periphery of the first vibrating diaphragm is fixed on the shell 40, the assembly is convenient, and a vibrating space for downward vibration of the first vibrating diaphragm is provided.

In one embodiment, as shown in fig. 11, the edges of the first magnet 312 are rounded to avoid collision with the first magnet 312 when the first sound generating unit 10 vibrates; in another embodiment, as shown in fig. 12, the corner of the first magnet 312 is cut to form the unfilled corner 3127, which can save cost.

In a specific embodiment, the first diaphragm includes an annular first reinforcing portion 11, an annular first ring 12, and an annular second ring 13, the outer periphery and the inner periphery of the first reinforcing portion 11 are respectively connected to the inner periphery of the first ring 12 and the outer periphery of the second ring 13, the first voice coil 14 is connected to one side of the first reinforcing portion 11 near the first magnetic gap, the first reinforcing portion 11 is located between the first ring 12 and the second ring 13, the first ring 12 has a first outer fixing portion 122 and a first inner fixing portion 121, the second ring 13 has a second outer fixing portion 132 and a second inner fixing portion 131, the outer periphery of the first reinforcing portion 11 is connected to the first inner fixing portion 121, the inner periphery of the first reinforcing portion 11 is connected to the second outer fixing portion 132, the first outer fixing portion 122 is connected to the housing 40, the second sounding unit 20 is covered above the second inner fixing portion 131, and the second inner fixing portion 131 is fixedly connected to the central magnetic circuit 31.

As shown in fig. 3 and 4, in some embodiments of the present invention, the sounding unit further includes a centering support 15, one side of the centering support 15 is fixed to the housing 40, and the other side is connected to an end of the first voice coil 14 away from the first diaphragm, so as to prevent the first sounding unit 10 from polarizing during vibration. The number of the centering support pieces 15 may be two, and they may be located at two ends of the sounding unit, or may be an integral structure, or may be four, and they are connected to four corners of the first voice coil 14, which is not limited in the present invention. Further, the centering support 15 is a conductive member, the inner side is provided with a pad connected with a lead (not shown) of the first voice coil 14, the outer side is provided with a pad electrically connected with an external circuit, and the centering support 15 not only realizes polarization prevention but also realizes electrical connection, and has multiple purposes and higher integration.

In one embodiment, the second diaphragm includes a second reinforcing portion 21 and a third gimbal 22, the second voice coil 23 is fixedly connected to a side of the second reinforcing portion 21 near the second magnetic gap, the third gimbal 22 has a third outer fixing portion 222 and a third inner fixing portion 221, the third outer fixing portion 222 is fixed to the fixing ring 25 or the protruding ring 3112, and the third inner fixing portion 221 is fixedly connected to an outer periphery of the second reinforcing portion 21, that is, the second reinforcing portion 21 is connected to an inner periphery of the third gimbal 22.

In another embodiment, as shown in fig. 17 and 18, the second diaphragm is a single planar diaphragm 200 or a second reinforcing portion 21 is provided on the planar diaphragm 200, and the second voice coil 23 is fixedly connected to the single planar diaphragm 200 or the second reinforcing portion 21 on the planar diaphragm 200. The planar diaphragm 200 may be made of PEN, carbon paper, or the like, and the second reinforcing portion 21 may be made of carbon paper, aluminum composite, or the like.

In one embodiment, as shown in fig. 7, an end of the first diaphragm, which is close to the second diaphragm, is fixed between the first magnetic conductive plate 311 and the first magnet 312. More specifically, the first magnetic conductive plate 311 is provided with a recess 3113 at an outer periphery thereof and near one side of the first magnet 312, and the second inner fixing portion 131 of the first diaphragm is located at the recess 3113, i.e., the second inner fixing portion 131 is located between the first magnetic conductive plate 311 and the first magnet 312, and the second inner fixing portion 131 is adhered to the first magnetic conductive plate 311 and/or the first magnet 312. The recess 3113 may be formed by pressing the outer periphery of the first magnetically permeable plate 311, or may be formed by removing material. Since the fixing ring 25 or the protruding ring 3112 is located above the outer periphery of the first magnetic conductive plate 311, the third outer fixing portion 222 of the second diaphragm is adhered to the fixing ring 25 or the protruding ring 3112, and there is an overlap between the adhesion surface of the third outer fixing portion 222 and the adhesion surface of the second inner fixing portion 131 projected in the first direction. The edges of the first vibrating diaphragm and the second vibrating diaphragm are ensured to have wider bonding widths, so that high-level waterproof can be realized under the condition that the vibration radiation area is not lost, for example, the waterproof requirement of 100 meters or more can be met. And under the condition that the vibration radiation areas are the same, smaller product volume can be obtained, and miniaturization is facilitated.

As shown in fig. 9, 10, 12, 15, 16 and 20, in some embodiments of the present invention, the sounding unit has an injection molding portion 24, which extends along a first direction, one end of the injection molding portion 24 is fixed to a first magnetic conductive plate 311, the central magnetic circuit 31 has a relief portion 315 for accommodating the injection molding portion 24, the yoke 33 has a limiting hole 331, and the other end of the injection molding portion 24 is fixed to the limiting hole 331. The electric connector 241 is embedded in the injection molding part 24, two ends of the electric connector 241 are provided with welding parts 2411, the first magnetic conduction plate 311 is provided with an opening 3111 and an avoiding part 316, the welding parts 2411 close to the second diaphragm are exposed, the welding parts 2411 close to the second diaphragm are connected with the lead 231 of the second voice coil 23, the avoiding part 316 is used for avoiding the lead 231 of the second voice coil 23, and the lead 231 is prevented from touching the first magnetic conduction plate 311; the first magnet 312 also has an avoiding portion 316 to prevent the lead wire 231 of the second voice coil 23 from touching the first magnet 312 when the second sound generating unit 20 vibrates downward. The soldering portion 2411 of the end of the electrical connector 241 remote from the second diaphragm is exposed through the limiting hole 331 and is connected to the soldering member 51 on the circuit board 50.

Further, the first magnetic conductive plate 311 has two openings 3111, two avoidance portions 316 and a gap, the two openings 3111 are respectively located at two ends of the gap and at two sides of the gap, and the two openings 3111 are centrally symmetrical; two avoidance portions 316 are located at two ends of the gap and at two sides of the gap, and adjacent avoidance portions 316 and openings 3111 are located at two sides of the gap. The two injection molding portions 24 are respectively corresponding to the two openings 3111, the two injection molding portions 24 are centrosymmetric with respect to the second voice coil 23, the two injection molding portions 24 are respectively located at two sides of the second voice coil 23, and the two leads 231 of the second voice coil 23 are respectively connected to the welding portions 2411 of the two electrical connectors 241 near the second diaphragm.

Further, the first magnet 312, the second magnetic conductive plate 313 and the second magnet 314 have two avoidance portions 315 and a gap, the two avoidance portions 315 are respectively located at two ends of the gap and at two sides of the gap, and the two avoidance portions 315 are centrosymmetric.

When the first magnet 312 is of a split structure, the first magnet 3121 has a relief portion 315 at one end portion thereof and a relief portion 316 at the other end portion thereof, and the third magnet 3123 has a relief portion 315 at one end portion thereof and a relief portion 316 at the other end portion thereof; when the second magnet 314 is of a split structure, the end portion inside the fourth magnet 3141 has the relief portion 315, the end portion inside the fifth magnet 3142 has the relief portion 315, and the relief portion 315 of the fourth magnet 3141 is centrosymmetric with the relief portion 315 of the fifth magnet 3142 with respect to the second voice coil 23.

In the above, the two injection molding portions 24 are centrosymmetric with respect to the second voice coil 23, the central magnetic circuit 31 has the avoiding portion 315, and the injection molding portions 24 are located in the avoiding portion 315, so as to ensure that the injection molding portions 24 do not interfere with the second voice coil 23, prevent the second voice coil 23 from touching the injection molding portions 24, and ensure that the two sides of the second voice coil 23 have sufficient second magnetic gaps. Through the structural design of the injection molding part 24, the electric connection of the lead wire 231 of the second voice coil 23 is facilitated, and meanwhile, the external bonding pad of the conductive piece and the external bonding pad of the circuit board 50 are led out from the same side.

In one embodiment, as shown in fig. 16, a groove 332 is disposed on a side of the yoke 33 away from the central magnetic circuit 31, the circuit board 50 is at least partially fixed in the groove 332, two limiting holes 331 are disposed in the groove 332, the ends of the two injection molding portions 24 away from the second diaphragm are positioned through the two limiting holes 331, and the welding portions 2411 of the ends of the electrical connecting pieces 241 of the two injection molding portions 24 away from the second diaphragm are exposed through the limiting holes 331, two welding pieces 51 are disposed on the circuit board 50, and the two welding pieces 51 are respectively located on two sides of the circuit board 50 and connected with the welding portions 2411. The thickness of the circuit board 50 is less than or equal to the depth of the groove 332, so that the circuit board 50 is protected, and the circuit board 50 is prevented from being knocked or worn by external devices.

In addition, as shown in fig. 20, the sound generating module includes a housing 60 and the sound generating units in the housing 60, the first sound generating unit 10 and the second sound generating unit 20 of the sound generating units are located on the same side of the magnetic circuit system 30, and the sound generated by the first sound generating unit 10 and the second sound generating unit 20 is converged and transmitted through the sound outlet of the sound generating module.

The invention also discloses electronic equipment which comprises the sounding module or the sounding monomer, and the electronic equipment can be a smart phone, a tablet personal computer, a PC, a wearable device, a head-mounted device and the like.

While certain specific embodiments of the invention have been described in detail by way of example, it will be appreciated by those skilled in the art that the above examples are for illustration only and are not intended to limit the scope of the invention. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.

Claims (13)

1. The sound production unit comprises a first sound production unit, a second sound production unit and a magnetic circuit system, and is characterized in that the first sound production unit comprises an annular first vibrating diaphragm and a first voice coil connected with the first vibrating diaphragm, the second sound production unit comprises a second vibrating diaphragm and a second voice coil connected with the second vibrating diaphragm, the second vibrating diaphragm is positioned at the inner periphery of the first vibrating diaphragm, the first vibrating diaphragm and the second vibrating diaphragm are coaxially arranged, and the first voice coil and the second voice coil vibrate along a first direction;

the magnetic circuit system comprises a central magnetic circuit and a side magnetic circuit which is positioned at the periphery of the central magnetic circuit, wherein the central magnetic circuit and the side magnetic circuit are arranged at intervals, a first magnetic gap is formed between the central magnetic circuit and the side magnetic circuit, and one side of the first voice coil, which is far away from the first vibrating diaphragm, is inserted into the first magnetic gap;

The central magnetic circuit is provided with a second magnetic gap, the second voice coil is a flat voice coil, the axis of the second voice coil extends along a second direction perpendicular to the first direction, and one side, away from the second vibrating diaphragm, of the second voice coil is inserted into the second magnetic gap.

2. The sound producing cell of claim 1, wherein the central magnetic circuit has a through-hole that forms the second magnetic gap.

3. The sound generating unit according to claim 2, wherein the central magnetic circuit has a first magnetic component, a second magnetic component, a third magnetic component and a fourth magnetic component, the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component enclose to form the through hole, the first magnetic component and the second magnetic component are located at two sides of the second voice coil along the second direction, and the third magnetic component and the fourth magnetic component are located at two sides of the second voice coil along a third direction perpendicular to the first direction and the second direction respectively.

4. The sound producing cell of claim 3, wherein the first, second, third and fourth magnetic assemblies are independent structures;

Or the first magnetic component and the third magnetic component are integrally formed, and the second magnetic component and the fourth magnetic component are integrally formed;

Or the first magnetic component, the second magnetic component, the third magnetic component and the fourth magnetic component are integrally formed.

5. The sound generating unit according to claim 1, wherein the central magnetic circuit includes a first magnetic conductive plate, a first magnet, a second magnetic conductive plate, and a second magnet stacked in this order along the first direction, and the second diaphragm is disposed opposite to the first magnetic conductive plate.

6. The sound producing cell of claim 5, wherein the first magnetically permeable plate, the first magnet, the second magnetically permeable plate, and the second magnet collectively define the second magnetic gap;

Or the first magnetic conduction plate, the first magnet and the second magnetic conduction plate jointly define the second magnetic gap, and the second magnetic gap is positioned on one side of the second magnet, which is close to the second vibrating diaphragm.

7. The sound generating unit according to claim 1, wherein the central magnetic circuit includes a first magnet, a second magnetic conductive plate, and a second magnet stacked in this order along the first direction, and the second diaphragm is disposed opposite to the first magnet.

8. The sound producing cell of claim 7, wherein the first magnet, the second magnetically permeable plate, and the second magnet collectively define the second magnetic gap;

or the first magnet and the second magnetic conduction plate jointly define the second magnetic gap, and the second magnetic gap is positioned at one side of the second magnet close to the second vibrating diaphragm.

9. The sound generating unit according to claim 5 or 7, wherein the first magnet includes a first magnet, a second magnet, and a third magnet magnetized in the first direction, the second magnet and the third magnet being located at one side of the second voice coil, the first magnet being located at the other side of the second voice coil, and the third magnet being located at one side of the second magnet away from the first magnet, in the second direction; the magnetizing direction of the first magnet is opposite to the magnetizing direction of the second magnet and the same as the magnetizing direction of the third magnet;

the second magnet comprises a fourth magnet and a fifth magnet which are magnetized along the first direction and have the same magnetizing direction, the fourth magnet and the fifth magnet are respectively positioned at two sides of the second voice coil along the second direction, and the magnetizing directions of the first magnet and the fourth magnet are opposite.

10. The sound generating unit according to claim 1, wherein the first diaphragm comprises an annular first reinforcing portion, an annular first folding ring and an annular second folding ring, the outer periphery and the inner periphery of the first reinforcing portion are respectively connected to the inner periphery of the first folding ring and the outer periphery of the second folding ring, and the first voice coil is connected to one side of the first reinforcing portion close to the first magnetic gap.

11. The sound generating unit according to any one of claims 1 to 10, wherein the second diaphragm includes a second reinforcing portion and a third folder, the second voice coil is connected to a side of the second reinforcing portion near the second magnetic gap, and the second reinforcing portion is connected to an inner periphery of the third folder;

or the second vibrating diaphragm is a plane vibrating diaphragm;

or the second vibrating diaphragm comprises a planar vibrating diaphragm and a second reinforcing part fixed on the planar vibrating diaphragm.

12. A sound module comprising a housing and a sound monomer according to any one of claims 1-11 located within the housing.

13. An electronic product, characterized in that the electronic product comprises the sounding module according to claim 12;

Or, the electronic product comprises the sounding monomer as defined in any one of claims 1 to 11.