EP3096537B1 - Wave-shaped suspension edge structure and vibration unit - Google Patents
Wave-shaped suspension edge structure and vibration unit Download PDFInfo
- Publication number
- EP3096537B1 EP3096537B1 EP15737028.9A EP15737028A EP3096537B1 EP 3096537 B1 EP3096537 B1 EP 3096537B1 EP 15737028 A EP15737028 A EP 15737028A EP 3096537 B1 EP3096537 B1 EP 3096537B1
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- European Patent Office
- Prior art keywords
- wave
- vibration
- shaped
- vibration element
- suspension edge
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- 239000000725 suspension Substances 0.000 title claims description 113
- 230000008093 supporting effect Effects 0.000 claims description 73
- 230000002093 peripheral effect Effects 0.000 claims description 26
- 239000011247 coating layer Substances 0.000 claims description 7
- 230000005236 sound signal Effects 0.000 claims description 6
- 230000004044 response Effects 0.000 claims description 5
- 239000000463 material Substances 0.000 claims description 3
- 230000008878 coupling Effects 0.000 claims description 2
- 238000010168 coupling process Methods 0.000 claims description 2
- 238000005859 coupling reaction Methods 0.000 claims description 2
- 230000003247 decreasing effect Effects 0.000 claims 1
- 238000006073 displacement reaction Methods 0.000 description 15
- 230000008901 benefit Effects 0.000 description 12
- 239000013013 elastic material Substances 0.000 description 12
- 230000003014 reinforcing effect Effects 0.000 description 11
- 230000000694 effects Effects 0.000 description 6
- 238000000465 moulding Methods 0.000 description 4
- 239000003292 glue Substances 0.000 description 3
- 238000000034 method Methods 0.000 description 3
- 230000008569 process Effects 0.000 description 3
- 230000001154 acute effect Effects 0.000 description 2
- 238000007796 conventional method Methods 0.000 description 2
- 230000007423 decrease Effects 0.000 description 2
- 230000001976 improved effect Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 230000008859 change Effects 0.000 description 1
- 229920001971 elastomer Polymers 0.000 description 1
- 230000005674 electromagnetic induction Effects 0.000 description 1
- 238000004049 embossing Methods 0.000 description 1
- 230000001939 inductive effect Effects 0.000 description 1
- 238000004519 manufacturing process Methods 0.000 description 1
- 230000000717 retained effect Effects 0.000 description 1
- 229920002725 thermoplastic elastomer Polymers 0.000 description 1
- 229920001187 thermosetting polymer Polymers 0.000 description 1
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 1
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Classifications
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R7/00—Diaphragms for electromechanical transducers; Cones
- H04R7/16—Mounting or tensioning of diaphragms or cones
- H04R7/18—Mounting or tensioning of diaphragms or cones at the periphery
- H04R7/20—Securing diaphragm or cone resiliently to support by flexible material, springs, cords, or strands
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2307/00—Details of diaphragms or cones for electromechanical transducers, their suspension or their manufacture covered by H04R7/00 or H04R31/003, not provided for in any of its subgroups
- H04R2307/207—Shape aspects of the outer suspension of loudspeaker diaphragms
Definitions
- the present invention relates to a wave-shaped suspension edge structure of a vibration unit of a loudspeaker.
- a conventional acoustic device such as a speaker, generally comprises a speaker frame, a vibration diaphragm supported by the speaker frame, a voice coil coupled at the vibration diaphragm, and a magnetic coil unit magnetically inducing with voice coil in order to drive the vibration diaphragm to vibrate for sound reproduction.
- the vibration diaphragm is mounted at an opening of the speaker frame, wherein when the voice coil is magnetically induced to reciprocatingly move, the vibration diaphragm is driven to vibrate correspondingly.
- the vibration direction of the vibration diaphragm is uncontrollable, such that the vibration diaphragm cannot reproduce good sound quality.
- the vibration diaphragm should only be reciprocatingly moved along one direction with even amplitude.
- the vibration diaphragm should only be reciprocatingly moved in a vertical (up-and-down) direction while the upward displacement of the vibration diaphragm should be the same as the downward displacement of the vibration diaphragm.
- a vibration unit of a typical conventional speaker is illustrated, the vibration unit can be used as a vibration system of a speaker to connect with the voice coil in response to the input of the audio signals, or the vibration unit can be used as a passive vibration unit to be driven by other speaker systems due to air pressure changes to reproduce an auxiliary sound.
- a vibration unit of a typical and conventional speaker comprises an intermediate vibration block 1, a suspension 2 around the vibration block 1 and an outer frame 3.
- the suspension 2 is arch-shaped and is coaxial with the vibration block 1.
- the suspension 2 cannot retain the vibration directions of the vibration block 1 in the axial direction. Because when the vibration block 1 deviates from the axial direction, the suspension 2 cannot apply a responding pulling force to prevent the deviating movement of the vibration block 1, while an eccentric force of the vibration block 1 does not decrease until being transferred to the connection of the suspension 2 and the outer frame 3. In other words, the suspension 2 cannot effectively prevent the vibration block 1 from deviating.
- FIG. 2A and Fig. 2B of the drawings a conventional solution is illustrated.
- a plurality of reinforcing ribs 4 is provided between the suspension 2 and the outer frame 3.
- the reinforcing ribs 4 provide a retaining effect so as to prevent the vibration block 1 deviating from the axial direction. In other words, when the vibration block 1 is about to deviate, the eccentric force will be transferred to these reinforcing ribs 4 so as to be offset.
- Fig. 2A and Fig. 2B of the drawings a conventional solution is illustrated.
- the reinforcing ribs 4 provide a retaining effect so as to prevent the vibration block 1 deviating from the axial direction. In other words, when the vibration block 1 is about to deviate, the eccentric force will be transferred to these reinforcing ribs 4 so as to be offset.
- the stroke of the vibration unit or the vibration diaphragm need to be as large as possible, and the solutions in the traditional audio devices usually are making a vibration unit or a vibration diaphragm with large size, as a result the conventional acoustic devices are not small enough. While many small sized devices with audio arrangement such as flat-panel TVs, mobile phones and laptops need to be flat and thin, so that the small sized devices can maintain compact product designs and unique shapes. The acoustic arrangement with a big size is not suitable for these small sized products.
- An advantage of the present invention according to claim 1 is to provide a wave-shaped suspension edge structure of a vibration unit, wherein the vibration unit comprises a vibration element, a supporting frame and an elastic suspension edge provided around the vibration element, the elastic suspension edge forms a wave shape along a circumferential direction of the center axis of the vibration unit, thereby effectively preventing the vibration element from shaking and deviating along the central axis direction.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the elastic suspension edge comprises a plurality of wave-shaped retaining sections formed around the vibration element, the plurality of wave-shaped retaining sections form a wave shape along the circumferential direction, so that the plurality of wave-shaped retaining sections retain the vibration element from radial deviation.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, in the conventional vibration unit, the radial cross section of the suspension is arch-shaped or wave-shaped, while the vibration unit of the present invention forms a wave-shaped shape along the circumferential direction of the central axis of the vibration element, thereby when the vibration element deviates from the center axis and moves along a radial direction, the wave-shaped structure formed by the wave-shaped retaining sections around can effectively prevent the radial deviation, so that the vibration element is retained in the axial direction.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, a wave-shaped suspension of a conventional vibration unit has a waveform extending along the circumferential direction of the vibrating element and the suspension of the conventional vibration unit cannot offset the eccentric force, while the elastic suspension edge of the present invention the can effectively provide an offset role to prevent the deviation of the vibrating element.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, a plurality of spaced grooves arranged annularly is formed around the vibration element, so that the elastic suspension edge forms a series of concave-convex structures around the vibration element, and the concave-convex structures can form a wave shape so as to prevent a further radial displacement of the vibration element.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the elastic suspension edge can be bonded with the supporting frame and the vibration element by glue, or during a forming process of the elastic suspension edge, the elastic material can be simultaneously coated on the vibrating element, so that the production method is easy and has a low cost.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the vibration unit can be used to make speakers or a passive vibration plate providing an auxiliary sound effect, and can also improve the sound quality especially the bass quality.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the vibration unit has a small size and volume and can reach to a larger stroke, so that the vibration unit of the present invention can be applied to compact digital products such as flat-panel TVs, mobile phones, laptops and so on.
- a wave-shaped suspension structure which is provided between a vibration element and a supporting frame, wherein the wave-shaped suspension edge structure comprises an elastic suspension edge provided around the vibration element and extended between the vibration element and the supporting frame, wherein the elastic suspension edge structure comprises a plurality of wave-shaped retaining sections forming a wave-shaped structure around the vibration element along a circumferential direction so as to restrict a movement direction of the vibration element to an axial direction and to prevent the vibration element from shaking and deviating.
- a groove is formed between two adjacent wave-shaped retaining sections so as to form the wave-shaped structure, wherein the shape of the wave-shaped structure is selected from the group consisting of sinusoidal waveform, sinusoidal waveform, triangular waveform and saw-tooth waveform.
- each of the wave-shaped retaining sections perpendicularly extends from an outer peripheral surface of the vibration element to an interior peripheral surface of the supporting frame.
- each of the wave-shaped retaining sections is slantedly extended from an outer peripheral surface of the vibration element to an interior peripheral surface of the supporting frame.
- each of the wave-shaped retaining sections which is connected to the vibration element has a sinusoidal waveform shaped inner edge.
- an inner edge of each of the wave-shaped retaining sections which is connected to the vibration element has a shape selected from the group consisting of sinusoidal waveform, sinusoidal waveform, triangular waveform and saw-tooth waveform.
- each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which is arc-shaped along a circumferential direction.
- each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which is sinusoidal-waveform-shaped.
- each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which is arc-shaped along a circumferential direction.
- each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which has a shape selected from the group consisting of sinusoidal waveform, sinusoidal waveform, triangular waveform and saw-tooth waveform.
- each vibration element connection end of each wave-shaped retaining section which is connected with the supporting frame, comprises two portions forming one angle therebetween.
- each supporting frame connection end of each wave-shaped retaining section comprises two portions forming one angle therebetween.
- supporting frame connection ends of each wave-shaped retaining sections are connected to each other to form a ring-shaped outer edge coaxial with the vibration element.
- the angle formed between the two portions of the vibration element connection ends is selected from the group consisting of an acute angle, a right angle and an obtuse angle.
- wave crests of the wave-shaped retaining sections have lower height than a level surface of an outer surface of the vibration element.
- wave crests of the wave-shaped retaining sections have higher height than a level surface of an outer surface of the vibration element.
- the plurality of wave-shaped retaining sections is arranged symmetrically relative to a center of the vibration element.
- the vibration element has a shape which is selected from the group consisting of circular, oval, rectangle, and polygon.
- the vibration element is circular-shaped and each wave-shaped retaining sections are arranged along a radial direction of the vibration element so as to form a radial configuration of the wave-shaped retaining sections.
- the number of the wave-shaped retaining sections is 2-200 and the ripple amplitude of each wave-shaped retaining sections is 1-500mm.
- the area of the vibration element is 0.005-0.2m 2 .
- the vibration element comprises a vibration weighted element and a coating layer coated on the vibration weighted element, and is made of same material with the elastic suspension edge.
- the elastic suspension edge is bonded with the supporting frame and the vibration element.
- the vibration unit is connected to a voice coil coupling with a magnetic coil system so as to form a loudspeaker.
- the vibration unit is a passive vibrating plate sharing a vibration cavity with at least one main vibration speaker, wherein the main vibration speaker makes response to input of audio signals to vibrate to produce sounds and the vibration unit is driven to vibrate to produce an auxiliary sound by the air pressure changes within the vibration cavity.
- the main vibration speaker and the vibration unit are arranged side by side.
- the main vibration speaker and the vibration unit are coaxial arranged back-to-back.
- a vibration unit 100 according to an example which is not part of the present invention is illustrated, wherein the vibration unit 100 comprises a vibration element 10 in the middle, and a suspension structure around the vibration element 10.
- the suspension structure comprises an elastic suspension edge 20 and a supporting frame 30 positioned around the elastic suspension edge 20.
- the elastic suspension edge 20 is made of an elastic material and extends between the vibration element 10 and the supporting frame 30 to confine the vibration of the vibration element 10.
- the shape of the vibration element 10 can be implied as circular, oval, square or other polygonal shape, in this preferred embodiment, the vibration element 10 is elliptical.
- the elastic suspension edge 20 correspondingly forms a substantially elliptical shape around the vibration element 10.
- the supporting frame 30 can have a variety of shapes, the present invention is not intended to be limiting in this aspect.
- the vibration unit 100 further comprises a plurality of retaining ribs 40 extending between the vibration element 10 and the supporting frame 30, so that an undulating structure is formed between the vibration element 10 and the supporting frame 30.
- the retaining ribs 40 are adapted for providing a confining effect to prevent the vibration element 10 deviating from the center axis of displacement. More specifically, when the vibration element 10 is about to deviate from the center axis to cause an deviation, the corresponding retaining ribs 40 produces an offset biasing force to counteract an eccentric force which causes a displacement of the vibration element 10.
- the retaining ribs 40 can extend along a direction which is perpendicular to an outer circumferential surface of the corresponding vibration element 10 and an inner circumferential surface of the corresponding supporting frame 30. As shown in Fig. 3 , the retaining ribs 40 can be provided along a radial direction of the vibration element 10 or be provided aslant. This arrangement can produce a corresponding tensile force along these directions so as to effectively prevent the vibration element 10 producing offset along these directions.
- the retaining ribs 40 can be uniformly arranged around the 10 and is symmetrically arranged with respect to the center of the vibration element 10.
- the retaining ribs 40 comprises a left retaining rib 401 and a right retaining rib 402.
- the vibration unit 100 When the vibration unit 100 is positioned vertically and operated normally, the vibration element 10 moves up and down along an axial direction.
- the right retaining rib 402 When the vibration element 10 is about to deviate to the left, the right retaining rib 402 immediately exerts a reverse tensile force along a right direction on the vibration element 10 so as to prevent the vibration element 10 from further deviating to the left.
- the left retaining rib 401 immediately exerts a reverse tensile force along a left direction on the vibration element 10 so as to prevent the vibration element 10 from further deviating to the right.
- the elastic suspension edge 20 and the retaining ribs 40 can effectively confine the vibration direction of the vibration element 10 between the upward and downward direction of the axial directions.
- the elastic suspension edge 20 can have a structure as shown in Fig. 1 , wherein the elastic suspension edge 20 is provided coaxially with the vibration element 10 and has a wave-shaped or arched cross section along a radial direction of the vibration element 10 as shown in Fig.5B so as to form a ring embossing along a central axis of the vibration element 10. It is worth mentioning that each of the retaining ribs 40 is protruded from the elastic suspension edge 20 to form the undulating structure in a circumferential direction of the vibration element 10.
- the "wave-shaped" of the present invention is not strictly similar to a wave formed by water, but is a drape structure or is similar to a corrugated paper structure formed around the vibration element 10.
- the plurality of retaining ribs 40 substantially divides the elastic suspension edge 20 to a plurality of suspension edge portions 201.
- the number of the retaining ribs 40 is not intended to be limiting, and can be adjusted according to different needs. In the example in the Fig. 3 , eight retaining ribs 40 divide the elastic suspension edge 20 into eight suspension edge portions 201.
- Each of the retaining ribs 40 is made of elastic materials and can be made of same or different elastic materials with the elastic suspension edge 20. When the retaining ribs 40 and the elastic suspension edge 20 are made of the same elastic materials, the plurality of retaining ribs 40 and the elastic suspension edge 20 can be molded in one piece.
- a mould is injected with a predetermined elastic material in one molding step, so that a combination with the plurality of retaining ribs 40 and the elastic suspension edge 20 is made.
- the predetermined elastic material can be coated with the vibration element 10 so as to form a elastic coating layer 12.
- the vibration element 10 comprises an internal vibration weighted element 11 and the external elastic coating layer 12.
- the elastic suspension edge 20 and the retaining ribs 40 can be bonded with the supporting frame 30 and the vibration element 10 using a conventional method by glue.
- the arched structure of the elastic suspension edge 20 can form a ring-shaped groove 202.
- Each of the retaining ribs 40 can be disposed on two sides of the elastic suspension edge 20 and bulges outwardly, or can be disposed on one side of the vibration element 10.
- each of the retaining ribs 40 and the ring-shaped groove 202 are positioned on two sides of the elastic suspension edge 20.
- each of the retaining ribs 40 is not extended into the ring-shaped groove 202 and is extended on one side of the vibration element 10, as shown in Fig. 5B , each of the retaining ribs 40 protrudes from the upper side of the vibration element 10. While a groove 203 is formed between two adjacent retaining ribs 40, so that the elastic suspension edge 20 and the retaining ribs 40 from a undulating structure around the vibration element 10.
- each of the retaining ribs 40 can be triangle, trapezoidal, rhombus and so on, so that not only each of the retaining ribs 40 is firmly located and connected with each other, but also does not hinder an axial motion of the vibration element 10. More specifically, in the example as shown in Fig.3 and Fig. 5A , each of the retaining ribs 40 is sheet-shaped and has a triangular cross section.
- the retaining ribs 40 can be connected with the vibration element 10 by one base of the triangle and is connected with the supporting frame 30 by one vertex of the triangle, or the retaining ribs 40 can be connected with the supporting frame 30 by one base of the triangle and is connected with the vibration element 10 by one vertex of the triangle.
- each of the retaining ribs 40 comprises a vibration element connecting end 41 and a supporting frame connecting end 42.
- the vibration element connecting end 41 and a outer peripheral surface 101 of the vibration element 10 are line-to-line connected, in other words, the base of the triangle of the retaining ribs 40 and the outer peripheral surface 101 of the vibration element 10 are connected to contact.
- the supporting frame connecting end 42 and an interior peripheral surface 301 of the supporting frame 30 are point-to-point connected, in other words, the vertex of the triangle of the retaining ribs 40 and the interior peripheral surface 301 of the supporting frame 30 are connected to contact.
- the shape of the triangle which is the cross section of the retaining ribs 40 can be any triangle shape, such as right-angled triangle, isosceles triangle, regular triangle and so on. It is worth mentioning that each side of these triangles can be straight line and curved line. As shown in Fig. 5A , the connected portion of each of the retaining ribs 40 and the elastic suspension edge 20 can be connected to form an arc shape.
- this design makes the connection strength of the retaining ribs 40 and the vibration element 10 bigger than the connection strength of the retaining ribs 40 and the supporting frame 30, so that at the same time the vibration element 10 is prevented from shifting, the pushing force which pushes the vibration element 10 to move axially is not quickly transferred to the supporting frame 30, while the stroke which is the axial displacement of the vibration element 10 is not greatly affected.
- the pulling force which is applied to the retaining ribs 40 by the supporting frame 30 and which pulls the vibration element 10 back to its initial position is not quickly transmitted to the vibration element 10, while the vibration element 10 is pulled to reach the maximum axial displacement as far as possible.
- the reinforcing ribs 4 and the vibration block 1 are connected line-to-line and have substantially rectangular cross-sections, in this way two ends of the reinforcing ribs 4 have a same connection structure with the vibration block 1 and with the outer frame 3, so that two ends of the reinforcing ribs 4 have a same connection strength.
- the pulling force which the outer frame 3 and the reinforcing ribs 4 pull back the vibration block 1 can apply to the vibration block 1 in real time, and the axial displacement of the vibration block 1 is influenced.
- each of the retaining ribs 40 is connected to the supporting frame 30 point-to-point, while other end thereof is connected to the vibration element 10 line-to-line, which not only prevents the vibration element 10 from swaying and shifting, but also not affect the axis displacement of the vibration element 10.
- a vibration unit 100A according to a first preferred embodiment of the present invention is illustrated, wherein the vibration unit 100A comprises a vibration element 10A and a wave-shaped suspension structure around the vibration element 10A.
- the wavy suspension structure comprises an elastic suspension edge 20A and a supporting frame 30A.
- the elastic suspension edge 20A extends between the vibration element 10A and the supporting frame 30A.
- the elastic suspension edge 20A forms a wave-shaped structure around the vibration element 10A along a circumferential direction thereof.
- the elastic suspension edge 20A comprises a plurality of wave-shaped retaining sections 21A disposed along the circumferential direction, so that the plurality of wave-shaped retaining sections 21A form the wave-shaped structure around the vibration element 10A. While the suspension 2 in Fig.1 only forms an arched or wave-shaped structure in a radial direction of the vibration block 1, so that the shifting of the vibration element 10A is not effectively prevented.
- the plurality of wave-shaped retaining sections 21A of the present invention is for providing a retaining effect, so as to prevent a displacement of the vibration element 10A deviating from a center X-axial. More specifically, when the vibration element 10A is about to deviate from the center X-axial to deviate in a certain direction, the corresponding wave-shaped retaining sections 21A applies a pulling force in an opposite direction to offset a deviation force which results in a deviation of the vibration element 10A. It is worth mentioning that these wave-shaped retaining sections 21A can be arranged evenly around the vibration element 10A and be arranged symmetrically relative to a center of the vibration element 10A.
- each of the wave-shaped retaining sections 21A comprises a left wave-shaped retaining section 21A and a right wave-shaped retaining section 21A.
- the vibration unit 100A When the vibration unit 100A is positioned vertically and operated normally, the vibration element 10A moves up and down along a X-axis.
- the vibration element 10A When the vibration element 10A is about to deviate to left along a Y-axial as shown in Fig. 6 , the vibration element 10A will be applied by a reversed pulling force to the right by the right wave-shaped retaining sections 21A so as to prevent the vibration element 10A from further deviating to the left. Otherwise, when the vibration element 10A is about to deviate to right along the Y-axial as shown in Fig.
- the vibration element l0A will be immediately applied by a reversed pulling force to the left by the left wave-shaped retaining sections 21A so as to prevent the vibration element 10A from further deviating to the right.
- the elastic suspension edge 20A is able to effectively limit a vibration direction of the vibration element 10A along an upward and downward direction of the X-axial.
- Each of the wave-shaped retaining sections 21A comprises a vibration element connection end 211A and a supporting frame connection end 212A.
- a cross section along a circumferential direction of the vibration element connection end 211A is wave-shaped and the vibration element connection end 211A is connected to an outer peripheral surface 101A of the vibration element 10A.
- the supporting frame connection end 212A is an outer edge, which is connected to an interior peripheral surface 301A of the supporting frame 30A. More specifically, to be described in more detail, as shown in Fig. 8 , in this preferred embodiment, the vibration element connection end 211A has two lower connection sites 2111A, 2112A and an upper connection site 2113A.
- the lines connecting the two lower connection site 2111A, 2112A and the upper connection site 2113A can form a triangle.
- Three connecting sites 2121A, 2122A and 2123A are respectively extended from the two lower connection site 2111A, 2112A and the upper connection site 2113A to the interior peripheral surface 301A of the supporting frame 30A.
- the three connecting sites 2121A, 2122A and 2123A are formed in the supporting frame connection end 212A and lines connecting the three connecting sites 2121A, 2122A and 2123A are along the interior peripheral surface 301 and are arc-shaped.
- the wave-shaped retaining sections 21A has an inner edge and an outer edge, and the inner edge connecting to the outer peripheral surface 101A of the vibration element 10A is wave-shaped or arch-shaped, the outer edge connecting to the interior peripheral surface 301A of the supporting frame 30A extends along the interior peripheral surface 301A of the supporting frame 30A and is arc-shaped and is positioned in a same level surface perpendicular to the center X-axis of the vibration element 10A.
- each of the wave-shaped retaining sections 21A is divided into two portions, an angle is formed between the two portions.
- the formed angle can be acute, right or obtuse angle.
- This wave-shaped structure of the present invention can prevent the vibration element 10A from skewing, and the pushing force which pushes the vibration element 10A to move axially will not quickly transferred to the supporting frame 30A, while the stroke of the vibration element 10A which is an axial displacement will not be greatly affected.
- a tensile force which the supporting frame 30A applies to the wave-shaped retaining sections 21A and which pulls the vibration element 10A back to its initial position will not be quickly transmitted to the vibration element 10A, so that the vibration element 10A reaches a maximum axial displacement to the greatest extent.
- the joint strength of the wave-shaped retaining sections 21A and the vibration element 10A is bigger than the joint strength of the wave-shaped retaining sections 21A and the supporting frame 30A.
- a connection structure of the inner edge of the wave-shaped retaining sections 21A and the vibration element 10A is triangular-shaped and is more stable, so that the joint strength of the wave-shaped retaining sections 21A and the vibration element 10A is stronger than the joint strength of the outer edge of the wave-shaped retaining sections 21A and the supporting frame 30A.
- the connection type can be reversed.
- the outer edge of the wave-shaped retaining sections 21A and the supporting frame 30A have a triangular-shaped connection structure, while the outer edge of the wave-shaped retaining sections 21A and the vibration element 10A have an arc-shaped connection in a same level surface rather than an undulating-shaped connection.
- a groove 203A is formed between the two adjacent wave-shaped retaining sections 21A, so that a series of the groove 203A which are arranged spaced apart are formed along a circumferential direction of the vibration element 10A and the wave-shaped structure is formed.
- the wave-shaped retaining sections 21A in the preferred embodiment of the present invention can be molded in one piece by using a mould injected with the predetermined elastic material in a molding step. It is worth mentioning that the in the molding process, the predetermined elastic material can be coated on the vibration element 10A so as to form an elastic coating layer 12A. In other words, as shown in Fig. 9 , the vibration element 10A comprises an internal vibration weighted element 11A and the external elastic coating layer 12A. It is worth mentioning that the elastic suspension edge 20A can also be bonded with the supporting frame 30A and the vibration element 10A using a conventional method by glue.
- the structure configuration in the alternative mode is similar to the structure configuration in the preferred embodiment except the formed wave height of the wave-shaped retaining sections 21A.
- the wave crest of each of the wave-shaped retaining sections 21A can be lower than an outer surface 102A of the vibration element 10A and can be lower than an outer surface 302A of the supporting frame 30A.
- the wave crest of each of the wave-shaped retaining sections 21A' can be higher than the outer surface 102A of the vibration element 10A and can be higher than the outer surface 302A of the supporting frame 30A.
- the resonant frequency of the vibration unit 100A is 5-200Hz
- the elastic suspension edge 20A can be made of any thermoset rubber or thermoplastic elastomer material.
- the elastic suspension edge 20A also has a predetermined rigidity.
- the shore hardness of the elastic suspension edge 20A preferably is about 5-85A.
- the ripple amplitude of each of the wave-shaped retaining sections 21A is 1-500mm and the ripple number of each of the wave-shaped retaining sections 21A is 2-100.
- the area size of the vibration element 10A is 0.005-0.2m 2 . It is worth mentioning that these detailed numerical values are only examples and are not intended to be limiting, and can be adjusted according to needs in practical use. It is worth mentioning that these detailed numerical values are suitable for the vibration units obtained in other embodiments of the present invention.
- the vibration unit 100A can be used as a vibration system of a speaker 1000A.
- the vibration element 10A of the vibration unit 100A is connected with a voice coil 110A.
- the voice coil 110A has an electromagnetic induction with a magnetic coil system 120A, so that when the speaker 1000A is input with the audio signal, the voice coil 110A is magnetically induced to reciprocating move in the magnetic field of the magnetic coil system 120A, so that the vibration element 10A is driven to vibrate to produce sound.
- the elastic suspension edge 20A of the present invention retains the movement of the vibration element 10A in the axial direction by the wave-shaped structure, so that the reproduced sound is purer.
- the vibration unit 100A can be used as a passive vibrating plate of a speaker 1000A'.
- the speaker 1000A' comprises a main vibration speaker 1100A' and the vibration unit 100A.
- the main vibration speaker 1100A' vibrates to produce sounds in response to the input of the audio signal.
- the vibration unit 100A and the main vibration speaker 1100A' share a vibration cavity 1200A'.
- the vibration unit 100A is also driven to vibrate to produce an auxiliary sound effect by means of the air pressure changes within the vibration cavity 1200A', so that the sound quality is improved, and especially the bass quality is strengthened.
- the main vibration speaker 1100A can be a conventional speaker structure and it can also be a horn or speaker made by the vibration unit 100A of the present invention.
- the speaker 1000A' comprises one or more main vibration speakers 1100A' and one or more vibration units 1100A and the main vibration speakers 1100A' and the vibration units 100A are arranged side by side or coaxial arranged back-to-back as shown in Fig. 11A .
- the speaker 1000A and the passive vibrating plate of the speaker 1000A both use the vibration unit 100A according to the preferred embodiment of the present invention.
- the vibration unit according to other embodiment can be applied to make the speaker 1000A and the passive vibrating plate of the speaker 1000A'.
- a vibration unit 100B according to an example which does not form part of the present invention is illustrated, wherein the vibration unit 100B comprises a vibration element 10B and a wave-shaped suspension structure around the vibration element 10B.
- the wary suspension structure comprises an elastic suspension edge elastic suspension edge 20B and a supporting frame 30B.
- the elastic suspension edge 20B is extended between the vibration element 10B and the supporting frame 30B.
- the elastic suspension edge 20B forms a wave-shaped structure around the vibration element 10B along a circumferential direction thereof.
- the elastic suspension edge 20B comprises a plurality of wave-shaped retaining sections 21B disposed along the circumferential direction, so that the plurality of wave-shaped retaining sections 21B form the wave-shaped structure around the vibration element 10B.
- the vibration unit 100B according to the example and the vibration unit 100A according to the example have a similar structure except that two ends of each of the wave-shaped retaining sections 21B which are a vibration element connection end 211B and a 212B have the same structure.
- an inner edge and an outer edge of the wave-shaped retaining sections 21B are wave-shaped or arch-shaped.
- an upper vertex and two lower bottom points are connected to form a triangle.
- the vibration element 10B is circular.
- the plurality of wave-shaped retaining sections 21B is disposed along a radial direction of the vibration element 10B so as to form a plurality of radial wave-shaped retaining sections 21B.
- the wave-shaped retaining sections 21B can be radially and coaxially arranged.
- the plurality of wave-shaped retaining sections 21B retains the position of the vibration element 10B in the radial direction to prevent the vibration element 10B deviates along a certain radial direction, so that the vibration element 10B only move along the axial direction.
- a vibration unit 100C in an alternative mode is illustrated, wherein the vibration unit 100C comprises a vibration element 10C and a wave-shaped suspension structure around the vibration element 10C.
- the wavy suspension structure comprises an elastic suspension edge 20C and a supporting frame 30C.
- the elastic suspension edge 20C is extended between the vibration element 10C and the supporting frame 30C.
- the elastic suspension edge 20C forms a wave-shaped structure around the vibration element 10C along a circumferential direction thereof.
- the elastic suspension edge 20C comprises multiple sets of connecting ribs 22C.
- Each set of the connecting ribs 22C comprise at least one top connecting rib 221C and at least one bottom connecting rib 222C adjacent to the top connecting rib 221C.
- the elastic suspension edge 20C further comprises a connecting section 23C respectively extended between the adjacent connecting ribs 22C (221C, 222C).
- the top connecting rib 221C is extended from the top side of an outer peripheral surface 101C of the vibration element 10C to an interior peripheral surface 301C of the supporting frame 30C.
- the bottom connecting rib 222C is extended from the bottom side of the outer peripheral surface 101C to the interior peripheral surface 301C of the supporting frame 30C.
- the arc-shaped connecting section 23C is formed between the top connecting rib 221C and the bottom connecting rib 222C.
- the connecting ribs 22C alternatively extend from the top side and the bottom side of the vibration element 10C to the supporting frame 30C, so that the elastic suspension edge 20C forms the wave-shaped structure around the vibration element 10C.
- the plurality of grooves 203C is also formed around the vibration element 10C.
- the connecting ribs 22C and the connecting section 23C can be made of different or same elastic materials.
- the elastic suspension edge 20C is made by injecting an elastic material into a mould such that the connecting ribs 22C and the connecting section 23C are integrally formed, so that a similar structure to the vibration unit 100B in the above first preferred embodiment is obtained.
- the vibration element 10C in the preferred embodiment of the present invention can be circular, so that these connecting ribs 22C are disposed along a radial direction of the vibration element 10C, so that the plurality of radial connecting ribs 22C are formed to prevent the vibration element 10C from skewing to the radial direction.
- a vibration unit 100D according to a second preferred embodiment of the present invention is illustrated, wherein the vibration unit 100D comprises a vibration element 10D and a wave-shaped suspension structure around the vibration element 10D.
- the wavy suspension structure comprises an elastic suspension edge 20D and a supporting frame 30D.
- the elastic suspension edge 20D is extended between the vibration element 10D and the supporting frame 30D.
- the elastic suspension edge 20D forms a wave-shaped structure around the vibration element 10D along a circumferential direction thereof.
- the vibration unit 100D according to the embodiment and the wave-shaped structure according to the first preferred embodiment have a similar structure, and the vibration unit 100D comprises a plurality of wave-shaped retaining sections 21D.
- each of the wave-shaped retaining sections 21D has a vibration element connection end 211D and a supporting frame connection end 212D.
- An outer edge which is the vibration element connection end 211D and which is connected to an outer peripheral surface 101D of the vibration element 10D does not form a sharp corner, and a rectangular will be obtained if connecting each vertexes.
- the waveform in this preferred embodiment is about square wave. It is expected that each above vertexes can be connected to form a trapezoid.
- the vibration unit 100D in this embodiment of the present invention is obtained by a transform of the vibration unit 100C in the previous example.
- the vibration unit 100D in the embodiment of the present invention is obtained.
- the vibration element connection end 211D which is an inner edge of the wave-shaped retaining sections 21D and which is connected to the outer peripheral surface 101D of the vibration element 10D can be a poly-line comprising different line segments
- the supporting frame connection end 212D which is an outer edge of the wave-shaped retaining sections 21D and which is connected to the interior peripheral surface 301D of the supporting frame 30D only forms one line, so that the connecting strength of the elastic suspension edge 20D and the vibration element 10D is bigger than the connecting strength of the elastic suspension edge 20D and the supporting frame 30D.
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- Physics & Mathematics (AREA)
- Acoustics & Sound (AREA)
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- Apparatuses For Generation Of Mechanical Vibrations (AREA)
- Audible-Bandwidth Dynamoelectric Transducers Other Than Pickups (AREA)
- Diaphragms For Electromechanical Transducers (AREA)
Description
- The present invention relates to a wave-shaped suspension edge structure of a vibration unit of a loudspeaker.
- A conventional acoustic device, such as a speaker, generally comprises a speaker frame, a vibration diaphragm supported by the speaker frame, a voice coil coupled at the vibration diaphragm, and a magnetic coil unit magnetically inducing with voice coil in order to drive the vibration diaphragm to vibrate for sound reproduction. In particular, the vibration diaphragm is mounted at an opening of the speaker frame, wherein when the voice coil is magnetically induced to reciprocatingly move, the vibration diaphragm is driven to vibrate correspondingly. However, the vibration direction of the vibration diaphragm is uncontrollable, such that the vibration diaphragm cannot reproduce good sound quality. In order to achieve better sound quality, the vibration diaphragm should only be reciprocatingly moved along one direction with even amplitude. For example, when the vibration diaphragm is placed horizontally, the vibration diaphragm should only be reciprocatingly moved in a vertical (up-and-down) direction while the upward displacement of the vibration diaphragm should be the same as the downward displacement of the vibration diaphragm.
- In other words, the conventional vibration diaphragm cannot move only along an axial direction, while the conventional vibration diaphragm will produce offset and shaking movement along the axial direction and will result in sounds which are not pure. As shown in
Fig. 1 , a vibration unit of a typical conventional speaker is illustrated, the vibration unit can be used as a vibration system of a speaker to connect with the voice coil in response to the input of the audio signals, or the vibration unit can be used as a passive vibration unit to be driven by other speaker systems due to air pressure changes to reproduce an auxiliary sound. As shown in the drawings, a vibration unit of a typical and conventional speaker comprises anintermediate vibration block 1, asuspension 2 around thevibration block 1 and anouter frame 3. Thesuspension 2 is arch-shaped and is coaxial with thevibration block 1. However, for the conventional vibration unit during a vibration period, thesuspension 2 cannot retain the vibration directions of thevibration block 1 in the axial direction. Because when thevibration block 1 deviates from the axial direction, thesuspension 2 cannot apply a responding pulling force to prevent the deviating movement of thevibration block 1, while an eccentric force of thevibration block 1 does not decrease until being transferred to the connection of thesuspension 2 and theouter frame 3. In other words, thesuspension 2 cannot effectively prevent thevibration block 1 from deviating. - As shown in
Fig. 2A and Fig. 2B of the drawings, a conventional solution is illustrated. A plurality of reinforcingribs 4 is provided between thesuspension 2 and theouter frame 3. The reinforcingribs 4 provide a retaining effect so as to prevent thevibration block 1 deviating from the axial direction. In other words, when thevibration block 1 is about to deviate, the eccentric force will be transferred to these reinforcingribs 4 so as to be offset. However, as shown inFig. 2B , it can be seen in a cross-section of the vibration unit that these reinforcingribs 4 contact with thevibration block 1 and theouter frame 3 line-to-line, so that when thevibration block 1 moves along the axial direction, a pull force in the axial direction will be affected by these reinforcingribs 4. In other words, although the reinforcingribs 4 has a certain effect on preventing deviating movement, thevibration block 1 has a displacement along the axial direction which decreases the stroke of the vibration unit, so that the whole stroke of the vibration unit is affected and the sound quality especially the bass sound quality is poor. - In addition, in order to obtain a better sound quality especially the bass quality, the stroke of the vibration unit or the vibration diaphragm need to be as large as possible, and the solutions in the traditional audio devices usually are making a vibration unit or a vibration diaphragm with large size, as a result the conventional acoustic devices are not small enough. While many small sized devices with audio arrangement such as flat-panel TVs, mobile phones and laptops need to be flat and thin, so that the small sized devices can maintain compact product designs and unique shapes. The acoustic arrangement with a big size is not suitable for these small sized products.
- An advantage of the present invention according to
claim 1 is to provide a wave-shaped suspension edge structure of a vibration unit, wherein the vibration unit comprises a vibration element, a supporting frame and an elastic suspension edge provided around the vibration element, the elastic suspension edge forms a wave shape along a circumferential direction of the center axis of the vibration unit, thereby effectively preventing the vibration element from shaking and deviating along the central axis direction. - Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the elastic suspension edge comprises a plurality of wave-shaped retaining sections formed around the vibration element, the plurality of wave-shaped retaining sections form a wave shape along the circumferential direction, so that the plurality of wave-shaped retaining sections retain the vibration element from radial deviation.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, in the conventional vibration unit, the radial cross section of the suspension is arch-shaped or wave-shaped, while the vibration unit of the present invention forms a wave-shaped shape along the circumferential direction of the central axis of the vibration element, thereby when the vibration element deviates from the center axis and moves along a radial direction, the wave-shaped structure formed by the wave-shaped retaining sections around can effectively prevent the radial deviation, so that the vibration element is retained in the axial direction.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, a wave-shaped suspension of a conventional vibration unit has a waveform extending along the circumferential direction of the vibrating element and the suspension of the conventional vibration unit cannot offset the eccentric force, while the elastic suspension edge of the present invention the can effectively provide an offset role to prevent the deviation of the vibrating element.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, a plurality of spaced grooves arranged annularly is formed around the vibration element, so that the elastic suspension edge forms a series of concave-convex structures around the vibration element, and the concave-convex structures can form a wave shape so as to prevent a further radial displacement of the vibration element.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the elastic suspension edge can be bonded with the supporting frame and the vibration element by glue, or during a forming process of the elastic suspension edge, the elastic material can be simultaneously coated on the vibrating element, so that the production method is easy and has a low cost.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the vibration unit can be used to make speakers or a passive vibration plate providing an auxiliary sound effect, and can also improve the sound quality especially the bass quality.
- Another advantage of the present invention is to provide a wave-shaped suspension edge structure of a vibration unit, the vibration unit has a small size and volume and can reach to a larger stroke, so that the vibration unit of the present invention can be applied to compact digital products such as flat-panel TVs, mobile phones, laptops and so on.
- Additional advantages and features of the invention will become apparent from the description which follows, and may be realized by means of the instrumentalities and combinations particular point out in the appended claims.
- According to the present invention, the foregoing and other objects and advantages are attained by a wave-shaped suspension structure according to
claim 1, which is provided between a vibration element and a supporting frame, wherein the wave-shaped suspension edge structure comprises an elastic suspension edge provided around the vibration element and extended between the vibration element and the supporting frame, wherein the elastic suspension edge structure comprises a plurality of wave-shaped retaining sections forming a wave-shaped structure around the vibration element along a circumferential direction so as to restrict a movement direction of the vibration element to an axial direction and to prevent the vibration element from shaking and deviating. - In one embodiment, a groove is formed between two adjacent wave-shaped retaining sections so as to form the wave-shaped structure, wherein the shape of the wave-shaped structure is selected from the group consisting of sinusoidal waveform, sinusoidal waveform, triangular waveform and saw-tooth waveform.
- In one embodiment, each of the wave-shaped retaining sections perpendicularly extends from an outer peripheral surface of the vibration element to an interior peripheral surface of the supporting frame.
- According to the invention, each of the wave-shaped retaining sections is slantedly extended from an outer peripheral surface of the vibration element to an interior peripheral surface of the supporting frame.
- In one embodiment, each of the wave-shaped retaining sections which is connected to the vibration element has a sinusoidal waveform shaped inner edge.
- In one embodiment, an inner edge of each of the wave-shaped retaining sections which is connected to the vibration element has a shape selected from the group consisting of sinusoidal waveform, sinusoidal waveform, triangular waveform and saw-tooth waveform.
- In one embodiment, each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which is arc-shaped along a circumferential direction.
- In one embodiment, each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which is sinusoidal-waveform-shaped.
- In one embodiment, each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which is arc-shaped along a circumferential direction.
- In one embodiment, each of the wave-shaped retaining sections which is connected to the supporting frame has an outer edge which has a shape selected from the group consisting of sinusoidal waveform, sinusoidal waveform, triangular waveform and saw-tooth waveform.
- In one embodiment, each vibration element connection end of each wave-shaped retaining section, which is connected with the supporting frame, comprises two portions forming one angle therebetween.
- In one embodiment, each supporting frame connection end of each wave-shaped retaining section comprises two portions forming one angle therebetween.
- In one embodiment, supporting frame connection ends of each wave-shaped retaining sections are connected to each other to form a ring-shaped outer edge coaxial with the vibration element.
- In one embodiment, the angle formed between the two portions of the vibration element connection ends is selected from the group consisting of an acute angle, a right angle and an obtuse angle.
- In one embodiment, wave crests of the wave-shaped retaining sections have lower height than a level surface of an outer surface of the vibration element.
- In one embodiment, wave crests of the wave-shaped retaining sections have higher height than a level surface of an outer surface of the vibration element.
- In one embodiment, the plurality of wave-shaped retaining sections is arranged symmetrically relative to a center of the vibration element.
- In one embodiment, the vibration element has a shape which is selected from the group consisting of circular, oval, rectangle, and polygon.
- In one embodiment, the vibration element is circular-shaped and each wave-shaped retaining sections are arranged along a radial direction of the vibration element so as to form a radial configuration of the wave-shaped retaining sections.
- In one embodiment, the number of the wave-shaped retaining sections is 2-200 and the ripple amplitude of each wave-shaped retaining sections is 1-500mm.
- In one embodiment, the area of the vibration element is 0.005-0.2m2.
- In one embodiment, the vibration element comprises a vibration weighted element and a coating layer coated on the vibration weighted element, and is made of same material with the elastic suspension edge.
- In one embodiment, the elastic suspension edge is bonded with the supporting frame and the vibration element.
- In one embodiment, the vibration unit is connected to a voice coil coupling with a magnetic coil system so as to form a loudspeaker.
- In one embodiment, the vibration unit is a passive vibrating plate sharing a vibration cavity with at least one main vibration speaker, wherein the main vibration speaker makes response to input of audio signals to vibrate to produce sounds and the vibration unit is driven to vibrate to produce an auxiliary sound by the air pressure changes within the vibration cavity.
- In one embodiment, the main vibration speaker and the vibration unit are arranged side by side.
- In one embodiment, the main vibration speaker and the vibration unit are coaxial arranged back-to-back.
- Still further objects and advantages will become apparent from a consideration of the ensuing description and drawings.
- These and other objectives, features, and advantages of the present invention will become apparent from the following detailed description, the accompanying drawings, and the appended claims.
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FIG. 1 is a schematic view of a vibration unit of a conventional speaker. -
FIG. 2A is a schematic view of an improved vibration unit of a conventional speaker. -
FIG. 2B is a schematic cross section view of theFIG. 2A along an A-A line. -
FIG. 3 is a perspective view of a vibration unit. -
FIG. 4 is an exploded perspective view of the vibration unit according tofigure 3 . -
FIG. 5A is a section view of theFIG. 3 along a B-B line. -
FIG. 5B is a section view of theFIG. 3 along a C-C line. -
FIG. 6 is a perspective view of a vibration unit with a wave-shaped suspension edge according to a preferred embodiment of the present invention. -
FIG. 7 is an exploded perspective view of the vibration unit according to the above preferred embodiment of the present invention. -
FIG. 8 is a partially enlarged schematic view of theFIG. 6 at a position of D. -
FIG. 9 is a section view of theFIG. 6 along a E-E line. -
FIG. 10A is a perspective view of the vibration unit applied to a loudspeaker according to the above preferred embodiment of the present invention. -
FIG. 10B is an exploded perspective view of the vibration unit applied to the loudspeaker according to above preferred embodiment of the present invention. -
FIG. 11A is a perspective view of the vibration unit applied to a passive vibration plate according to the above preferred embodiment of the present invention. -
FIG. 11B is an exploded perspective view of the vibration unit applied to the passive vibration plate according to above preferred embodiment of the present invention. -
FIG. 12 is a perspective view of a vibration unit according to an alternative mode of the preferred embodiment of the present invention. -
FIG. 13 is an exploded perspective view of the vibration unit according to the alternative mode of above preferred embodiment of the present invention. -
FIG. 14 is a partially enlarged schematic view of theFIG. 12 at a position of F. -
FIG. 15 is a section view of theFIG. 12 along a F-F line. -
FIG. 16 is a perspective view of a vibration unit with a wave-shaped suspension edge. -
FIG. 17 is an exploded perspective view of the vibration unit according to the abovefigure 16 . -
FIG. 18 is a partially enlarged schematic view of theFIG. 16 at a position of H. -
FIG. 19 is a section view of theFIG. 16 along a I-I line. -
FIG. 20 is a perspective view of a vibration unit according to an alternative mode of the the abovefigure 16 . -
FIG. 21 is an exploded perspective view of the vibration unit according to the alternative mode of abovefigure 16 . -
FIG. 22 is a partially enlarged schematic view of theFIG. 20 at a position of I. -
FIG. 23 is a section view of theFIG. 20 along a K-K line. -
FIG. 24 is a perspective view of a vibration unit with a wave-shaped suspension edge according to a second preferred embodiment of the present invention. -
FIG. 25 is an exploded perspective view of the vibration unit according to above second preferred embodiment of the present invention. -
FIG. 26 is a partially enlarged schematic view of theFIG. 24 at a position of L. -
FIG. 27 is a section view of theFIG. 24 along a M-M line. - The following description is disclosed to enable any person skilled in the art to make and use the present invention. Preferred embodiments are provided in the following description only as examples and modifications will be apparent to those skilled in the art.
- Referring to
Fig. 3 to Fig. 5B of the drawings, avibration unit 100 according to an example which is not part of the present invention is illustrated, wherein thevibration unit 100 comprises avibration element 10 in the middle, and a suspension structure around thevibration element 10. The suspension structure comprises anelastic suspension edge 20 and a supportingframe 30 positioned around theelastic suspension edge 20. In other words, theelastic suspension edge 20 is made of an elastic material and extends between thevibration element 10 and the supportingframe 30 to confine the vibration of thevibration element 10. The shape of thevibration element 10 can be implied as circular, oval, square or other polygonal shape, in this preferred embodiment, thevibration element 10 is elliptical. Theelastic suspension edge 20 correspondingly forms a substantially elliptical shape around thevibration element 10. The supportingframe 30 can have a variety of shapes, the present invention is not intended to be limiting in this aspect. - In this example, the
vibration unit 100 further comprises a plurality of retainingribs 40 extending between thevibration element 10 and the supportingframe 30, so that an undulating structure is formed between thevibration element 10 and the supportingframe 30. The retainingribs 40 are adapted for providing a confining effect to prevent thevibration element 10 deviating from the center axis of displacement. More specifically, when thevibration element 10 is about to deviate from the center axis to cause an deviation, the corresponding retainingribs 40 produces an offset biasing force to counteract an eccentric force which causes a displacement of thevibration element 10. It is worth mentioning that the retainingribs 40 can extend along a direction which is perpendicular to an outer circumferential surface of the correspondingvibration element 10 and an inner circumferential surface of the corresponding supportingframe 30. As shown inFig. 3 , the retainingribs 40 can be provided along a radial direction of thevibration element 10 or be provided aslant. This arrangement can produce a corresponding tensile force along these directions so as to effectively prevent thevibration element 10 producing offset along these directions. - It is worth mentioning that the retaining
ribs 40 can be uniformly arranged around the 10 and is symmetrically arranged with respect to the center of thevibration element 10. For example, as shown inFig.3 , the retainingribs 40 comprises aleft retaining rib 401 and aright retaining rib 402. When thevibration unit 100 is positioned vertically and operated normally, thevibration element 10 moves up and down along an axial direction. When thevibration element 10 is about to deviate to the left, theright retaining rib 402 immediately exerts a reverse tensile force along a right direction on thevibration element 10 so as to prevent thevibration element 10 from further deviating to the left. On the contrary, when thevibration element 10 is about to deviate to the right, theleft retaining rib 401 immediately exerts a reverse tensile force along a left direction on thevibration element 10 so as to prevent thevibration element 10 from further deviating to the right. Thus, theelastic suspension edge 20 and the retainingribs 40 can effectively confine the vibration direction of thevibration element 10 between the upward and downward direction of the axial directions. - The
elastic suspension edge 20 can have a structure as shown inFig. 1 , wherein theelastic suspension edge 20 is provided coaxially with thevibration element 10 and has a wave-shaped or arched cross section along a radial direction of thevibration element 10 as shown inFig.5B so as to form a ring embossing along a central axis of thevibration element 10. It is worth mentioning that each of the retainingribs 40 is protruded from theelastic suspension edge 20 to form the undulating structure in a circumferential direction of thevibration element 10. In other words, the "wave-shaped" of the present invention is not strictly similar to a wave formed by water, but is a drape structure or is similar to a corrugated paper structure formed around thevibration element 10. - As shown in
Fig. 3 , the plurality of retainingribs 40 substantially divides theelastic suspension edge 20 to a plurality of suspension edge portions 201. The number of the retainingribs 40 is not intended to be limiting, and can be adjusted according to different needs. In the example in theFig. 3 , eight retainingribs 40 divide theelastic suspension edge 20 into eight suspension edge portions 201. Each of the retainingribs 40 is made of elastic materials and can be made of same or different elastic materials with theelastic suspension edge 20. When the retainingribs 40 and theelastic suspension edge 20 are made of the same elastic materials, the plurality of retainingribs 40 and theelastic suspension edge 20 can be molded in one piece. In other words, a mould is injected with a predetermined elastic material in one molding step, so that a combination with the plurality of retainingribs 40 and theelastic suspension edge 20 is made. It is worth mentioning that the in the molding process, the predetermined elastic material can be coated with thevibration element 10 so as to form aelastic coating layer 12. In other words, thevibration element 10 comprises an internal vibrationweighted element 11 and the externalelastic coating layer 12. It is worth mentioning that theelastic suspension edge 20 and the retainingribs 40 can be bonded with the supportingframe 30 and thevibration element 10 using a conventional method by glue. - As shown in
Fig. 5B , it is worth mentioning that the arched structure of theelastic suspension edge 20 can form a ring-shapedgroove 202. Each of the retainingribs 40 can be disposed on two sides of theelastic suspension edge 20 and bulges outwardly, or can be disposed on one side of thevibration element 10. In this example, each of the retainingribs 40 and the ring-shapedgroove 202 are positioned on two sides of theelastic suspension edge 20. In other words, each of the retainingribs 40 is not extended into the ring-shapedgroove 202 and is extended on one side of thevibration element 10, as shown inFig. 5B , each of the retainingribs 40 protrudes from the upper side of thevibration element 10. While agroove 203 is formed between two adjacent retainingribs 40, so that theelastic suspension edge 20 and the retainingribs 40 from a undulating structure around thevibration element 10. - As shown in
Fig. 3 andFig. 5A , the shape of the cross section of each of the retainingribs 40 can be triangle, trapezoidal, rhombus and so on, so that not only each of the retainingribs 40 is firmly located and connected with each other, but also does not hinder an axial motion of thevibration element 10. More specifically, in the example as shown inFig.3 andFig. 5A , each of the retainingribs 40 is sheet-shaped and has a triangular cross section. The retainingribs 40 can be connected with thevibration element 10 by one base of the triangle and is connected with the supportingframe 30 by one vertex of the triangle, or the retainingribs 40 can be connected with the supportingframe 30 by one base of the triangle and is connected with thevibration element 10 by one vertex of the triangle. - Preferably, each of the retaining
ribs 40 comprises a vibrationelement connecting end 41 and a supportingframe connecting end 42. The vibrationelement connecting end 41 and a outerperipheral surface 101 of thevibration element 10 are line-to-line connected, in other words, the base of the triangle of the retainingribs 40 and the outerperipheral surface 101 of thevibration element 10 are connected to contact. The supportingframe connecting end 42 and an interiorperipheral surface 301 of the supportingframe 30 are point-to-point connected, in other words, the vertex of the triangle of the retainingribs 40 and the interiorperipheral surface 301 of the supportingframe 30 are connected to contact. It is worth mentioning that the shape of the triangle which is the cross section of the retainingribs 40 can be any triangle shape, such as right-angled triangle, isosceles triangle, regular triangle and so on. It is worth mentioning that each side of these triangles can be straight line and curved line. As shown inFig. 5A , the connected portion of each of the retainingribs 40 and theelastic suspension edge 20 can be connected to form an arc shape. - It is worth mentioning that this design makes the connection strength of the retaining
ribs 40 and thevibration element 10 bigger than the connection strength of the retainingribs 40 and the supportingframe 30, so that at the same time thevibration element 10 is prevented from shifting, the pushing force which pushes thevibration element 10 to move axially is not quickly transferred to the supportingframe 30, while the stroke which is the axial displacement of thevibration element 10 is not greatly affected. In other words, the pulling force which is applied to the retainingribs 40 by the supportingframe 30 and which pulls thevibration element 10 back to its initial position is not quickly transmitted to thevibration element 10, while thevibration element 10 is pulled to reach the maximum axial displacement as far as possible. In other words, it cannot make that when the retainingribs 40 just begins the axial displacement from the middle initial position, the retainingribs 40 shortens the axial displacement due to the affect of a restoring force immediately applied by the supportingframe 30. - In other words, as shown in
Fig. 2A and Fig. 2B , the reinforcingribs 4 and thevibration block 1 are connected line-to-line and have substantially rectangular cross-sections, in this way two ends of the reinforcingribs 4 have a same connection structure with thevibration block 1 and with theouter frame 3, so that two ends of the reinforcingribs 4 have a same connection strength. Thus, the pulling force which theouter frame 3 and the reinforcingribs 4 pull back thevibration block 1 can apply to thevibration block 1 in real time, and the axial displacement of thevibration block 1 is influenced. In other words, although the reinforcingribs 4 has an affect on reducing the shifting of thevibration block 1, at the same time the stroke of thevibration block 1 has a serious negative impact. In the present invention, one end of each of the retainingribs 40 is connected to the supportingframe 30 point-to-point, while other end thereof is connected to thevibration element 10 line-to-line, which not only prevents thevibration element 10 from swaying and shifting, but also not affect the axis displacement of thevibration element 10. - Referring to
Fig. 6 to Fig. 11B , avibration unit 100A according to a first preferred embodiment of the present invention is illustrated, wherein thevibration unit 100A comprises avibration element 10A and a wave-shaped suspension structure around thevibration element 10A. The wavy suspension structure comprises anelastic suspension edge 20A and a supportingframe 30A. Theelastic suspension edge 20A extends between thevibration element 10A and the supportingframe 30A. In this embodiment, theelastic suspension edge 20A forms a wave-shaped structure around thevibration element 10A along a circumferential direction thereof. - Specifically, the
elastic suspension edge 20A comprises a plurality of wave-shapedretaining sections 21A disposed along the circumferential direction, so that the plurality of wave-shapedretaining sections 21A form the wave-shaped structure around thevibration element 10A. While thesuspension 2 inFig.1 only forms an arched or wave-shaped structure in a radial direction of thevibration block 1, so that the shifting of thevibration element 10A is not effectively prevented. - The plurality of wave-shaped
retaining sections 21A of the present invention is for providing a retaining effect, so as to prevent a displacement of thevibration element 10A deviating from a center X-axial. More specifically, when thevibration element 10A is about to deviate from the center X-axial to deviate in a certain direction, the corresponding wave-shapedretaining sections 21A applies a pulling force in an opposite direction to offset a deviation force which results in a deviation of thevibration element 10A. It is worth mentioning that these wave-shapedretaining sections 21A can be arranged evenly around thevibration element 10A and be arranged symmetrically relative to a center of thevibration element 10A. - For example, as shown in
Fig. 6 , each of the wave-shapedretaining sections 21A comprises a left wave-shapedretaining section 21A and a right wave-shapedretaining section 21A. When thevibration unit 100A is positioned vertically and operated normally, thevibration element 10A moves up and down along a X-axis. When thevibration element 10A is about to deviate to left along a Y-axial as shown inFig. 6 , thevibration element 10A will be applied by a reversed pulling force to the right by the right wave-shapedretaining sections 21A so as to prevent thevibration element 10A from further deviating to the left. Otherwise, when thevibration element 10A is about to deviate to right along the Y-axial as shown inFig. 6 , the vibration element l0A will be immediately applied by a reversed pulling force to the left by the left wave-shapedretaining sections 21A so as to prevent thevibration element 10A from further deviating to the right. Thus, theelastic suspension edge 20A is able to effectively limit a vibration direction of thevibration element 10A along an upward and downward direction of the X-axial. - Each of the wave-shaped
retaining sections 21A comprises a vibrationelement connection end 211A and a supporting frame connection end 212A. As shown inFig. 8 , a cross section along a circumferential direction of the vibrationelement connection end 211A is wave-shaped and the vibrationelement connection end 211A is connected to an outerperipheral surface 101A of thevibration element 10A. The supportingframe connection end 212A is an outer edge, which is connected to an interiorperipheral surface 301A of the supportingframe 30A. More specifically, to be described in more detail, as shown inFig. 8 , in this preferred embodiment, the vibrationelement connection end 211A has twolower connection sites upper connection site 2113A. The lines connecting the twolower connection site upper connection site 2113A can form a triangle. Three connectingsites lower connection site upper connection site 2113A to the interiorperipheral surface 301A of the supportingframe 30A. The three connectingsites sites peripheral surface 301 and are arc-shaped. In other words, in this embodiment, the wave-shapedretaining sections 21A has an inner edge and an outer edge, and the inner edge connecting to the outerperipheral surface 101A of thevibration element 10A is wave-shaped or arch-shaped, the outer edge connecting to the interiorperipheral surface 301A of the supportingframe 30A extends along the interiorperipheral surface 301A of the supportingframe 30A and is arc-shaped and is positioned in a same level surface perpendicular to the center X-axis of thevibration element 10A. - In other words, the vibration
element connection end 211A of each of the wave-shapedretaining sections 21A is divided into two portions, an angle is formed between the two portions. The formed angle can be acute, right or obtuse angle. - This wave-shaped structure of the present invention can prevent the
vibration element 10A from skewing, and the pushing force which pushes thevibration element 10A to move axially will not quickly transferred to the supportingframe 30A, while the stroke of thevibration element 10A which is an axial displacement will not be greatly affected. In other words, a tensile force which the supportingframe 30A applies to the wave-shapedretaining sections 21A and which pulls thevibration element 10A back to its initial position will not be quickly transmitted to thevibration element 10A, so that thevibration element 10A reaches a maximum axial displacement to the greatest extent. - It is worth mentioning that, in this preferred embodiment, the joint strength of the wave-shaped
retaining sections 21A and thevibration element 10A is bigger than the joint strength of the wave-shapedretaining sections 21A and the supportingframe 30A. In other words, a connection structure of the inner edge of the wave-shapedretaining sections 21A and thevibration element 10A is triangular-shaped and is more stable, so that the joint strength of the wave-shapedretaining sections 21A and thevibration element 10A is stronger than the joint strength of the outer edge of the wave-shapedretaining sections 21A and the supportingframe 30A. One skilled in the art shall understand that the connection type can be reversed. In other words, the outer edge of the wave-shapedretaining sections 21A and the supportingframe 30A have a triangular-shaped connection structure, while the outer edge of the wave-shapedretaining sections 21A and thevibration element 10A have an arc-shaped connection in a same level surface rather than an undulating-shaped connection. - In addition, a
groove 203A is formed between the two adjacent wave-shapedretaining sections 21A, so that a series of thegroove 203A which are arranged spaced apart are formed along a circumferential direction of thevibration element 10A and the wave-shaped structure is formed. - It is worth mentioning that the wave-shaped
retaining sections 21A in the preferred embodiment of the present invention can be molded in one piece by using a mould injected with the predetermined elastic material in a molding step. It is worth mentioning that the in the molding process, the predetermined elastic material can be coated on thevibration element 10A so as to form anelastic coating layer 12A. In other words, as shown inFig. 9 , thevibration element 10A comprises an internal vibrationweighted element 11A and the externalelastic coating layer 12A. It is worth mentioning that theelastic suspension edge 20A can also be bonded with the supportingframe 30A and thevibration element 10A using a conventional method by glue. - Referring to
Fig. 12 to Fig. 15 of the drawings, an alternative mode according to the preferred embodiment of the present invention is illustrated. The structure configuration in the alternative mode is similar to the structure configuration in the preferred embodiment except the formed wave height of the wave-shapedretaining sections 21A. As shown inFig. 9 , the wave crest of each of the wave-shapedretaining sections 21A can be lower than anouter surface 102A of thevibration element 10A and can be lower than anouter surface 302A of the supportingframe 30A. However, as shown inFig. 15 , the wave crest of each of the wave-shapedretaining sections 21A' can be higher than theouter surface 102A of thevibration element 10A and can be higher than theouter surface 302A of the supportingframe 30A. - It is worth mentioning that according to the embodiment, the resonant frequency of the
vibration unit 100A is 5-200Hz, and theelastic suspension edge 20A can be made of any thermoset rubber or thermoplastic elastomer material. Theelastic suspension edge 20A also has a predetermined rigidity. For example, the shore hardness of theelastic suspension edge 20A preferably is about 5-85A. The ripple amplitude of each of the wave-shapedretaining sections 21A is 1-500mm and the ripple number of each of the wave-shapedretaining sections 21A is 2-100. Preferably, the area size of thevibration element 10A is 0.005-0.2m2. It is worth mentioning that these detailed numerical values are only examples and are not intended to be limiting, and can be adjusted according to needs in practical use. It is worth mentioning that these detailed numerical values are suitable for the vibration units obtained in other embodiments of the present invention. - As shown in
Fig. 10A andFig. 10B , thevibration unit 100A according to the preferred embodiment of the present invention can be used as a vibration system of aspeaker 1000A. Thevibration element 10A of thevibration unit 100A is connected with avoice coil 110A. Thevoice coil 110A has an electromagnetic induction with amagnetic coil system 120A, so that when thespeaker 1000A is input with the audio signal, thevoice coil 110A is magnetically induced to reciprocating move in the magnetic field of themagnetic coil system 120A, so that thevibration element 10A is driven to vibrate to produce sound. Theelastic suspension edge 20A of the present invention retains the movement of thevibration element 10A in the axial direction by the wave-shaped structure, so that the reproduced sound is purer. - As shown in
Fig. 11A andFig. 11B , thevibration unit 100A according to the preferred embodiment of the present invention can be used as a passive vibrating plate of aspeaker 1000A'. Specifically, thespeaker 1000A' comprises amain vibration speaker 1100A' and thevibration unit 100A. Themain vibration speaker 1100A' vibrates to produce sounds in response to the input of the audio signal. Thevibration unit 100A and themain vibration speaker 1100A' share avibration cavity 1200A'. When themain vibration speaker 1100A' vibrates, thevibration unit 100A is also driven to vibrate to produce an auxiliary sound effect by means of the air pressure changes within thevibration cavity 1200A', so that the sound quality is improved, and especially the bass quality is strengthened. - The
main vibration speaker 1100A can be a conventional speaker structure and it can also be a horn or speaker made by thevibration unit 100A of the present invention. Thespeaker 1000A' comprises one or moremain vibration speakers 1100A' and one ormore vibration units 1100A and themain vibration speakers 1100A' and thevibration units 100A are arranged side by side or coaxial arranged back-to-back as shown inFig. 11A . - It is worth mentioning that the
speaker 1000A and the passive vibrating plate of thespeaker 1000A both use thevibration unit 100A according to the preferred embodiment of the present invention. The vibration unit according to other embodiment can be applied to make thespeaker 1000A and the passive vibrating plate of thespeaker 1000A'. - Referring to
Fig. 16 to Fig. 19 of the drawings, avibration unit 100B according to an example which does not form part of the present invention is illustrated, wherein thevibration unit 100B comprises avibration element 10B and a wave-shaped suspension structure around thevibration element 10B. The wary suspension structure comprises an elastic suspension edgeelastic suspension edge 20B and a supportingframe 30B. Theelastic suspension edge 20B is extended between thevibration element 10B and the supportingframe 30B. In this embodiment, theelastic suspension edge 20B forms a wave-shaped structure around thevibration element 10B along a circumferential direction thereof. - Specifically, the
elastic suspension edge 20B comprises a plurality of wave-shapedretaining sections 21B disposed along the circumferential direction, so that the plurality of wave-shapedretaining sections 21B form the wave-shaped structure around thevibration element 10B. Thevibration unit 100B according to the example and thevibration unit 100A according to the example have a similar structure except that two ends of each of the wave-shapedretaining sections 21B which are a vibrationelement connection end 211B and a 212B have the same structure. In other words, an inner edge and an outer edge of the wave-shapedretaining sections 21B are wave-shaped or arch-shaped. As shown inFig. 18 , an upper vertex and two lower bottom points are connected to form a triangle. - It is worth mentioning that, in the example, the
vibration element 10B is circular. The plurality of wave-shapedretaining sections 21B is disposed along a radial direction of thevibration element 10B so as to form a plurality of radial wave-shapedretaining sections 21B. In other words, the wave-shapedretaining sections 21B can be radially and coaxially arranged. The plurality of wave-shapedretaining sections 21B retains the position of thevibration element 10B in the radial direction to prevent thevibration element 10B deviates along a certain radial direction, so that thevibration element 10B only move along the axial direction. - Referring to
Fig. 20 to Fig. 23 of the drawings, avibration unit 100C in an alternative mode according to the example is illustrated, wherein thevibration unit 100C comprises avibration element 10C and a wave-shaped suspension structure around thevibration element 10C. The wavy suspension structure comprises anelastic suspension edge 20C and a supportingframe 30C. Theelastic suspension edge 20C is extended between thevibration element 10C and the supportingframe 30C. In this embodiment, theelastic suspension edge 20C forms a wave-shaped structure around thevibration element 10C along a circumferential direction thereof. - Specifically, the
elastic suspension edge 20C comprises multiple sets of connectingribs 22C. Each set of the connectingribs 22C comprise at least onetop connecting rib 221C and at least onebottom connecting rib 222C adjacent to thetop connecting rib 221C. Theelastic suspension edge 20C further comprises a connectingsection 23C respectively extended between the adjacent connectingribs 22C (221C, 222C). - In the preferred embodiment of the present invention, the
top connecting rib 221C is extended from the top side of an outerperipheral surface 101C of thevibration element 10C to an interiorperipheral surface 301C of the supportingframe 30C. Thebottom connecting rib 222C is extended from the bottom side of the outerperipheral surface 101C to the interiorperipheral surface 301C of the supportingframe 30C. The arc-shaped connectingsection 23C is formed between the top connectingrib 221C and thebottom connecting rib 222C. - The connecting
ribs 22C alternatively extend from the top side and the bottom side of thevibration element 10C to the supportingframe 30C, so that theelastic suspension edge 20C forms the wave-shaped structure around thevibration element 10C. Similarly, the plurality ofgrooves 203C is also formed around thevibration element 10C. - The connecting
ribs 22C and the connectingsection 23C can be made of different or same elastic materials. When the connectingribs 22C and the connectingsection 23C are made of the same elastic materials, theelastic suspension edge 20C is made by injecting an elastic material into a mould such that the connectingribs 22C and the connectingsection 23C are integrally formed, so that a similar structure to thevibration unit 100B in the above first preferred embodiment is obtained. - The
vibration element 10C in the preferred embodiment of the present invention can be circular, so that these connectingribs 22C are disposed along a radial direction of thevibration element 10C, so that the plurality ofradial connecting ribs 22C are formed to prevent thevibration element 10C from skewing to the radial direction. - Referring to
Fig. 24 to Fig. 27 , avibration unit 100D according to a second preferred embodiment of the present invention is illustrated, wherein thevibration unit 100D comprises avibration element 10D and a wave-shaped suspension structure around thevibration element 10D. The wavy suspension structure comprises anelastic suspension edge 20D and a supportingframe 30D. Theelastic suspension edge 20D is extended between thevibration element 10D and the supportingframe 30D. In this embodiment, theelastic suspension edge 20D forms a wave-shaped structure around thevibration element 10D along a circumferential direction thereof. - The
vibration unit 100D according to the embodiment and the wave-shaped structure according to the first preferred embodiment have a similar structure, and thevibration unit 100D comprises a plurality of wave-shapedretaining sections 21D. each of the wave-shapedretaining sections 21D has a vibrationelement connection end 211D and a supportingframe connection end 212D. An outer edge which is the vibrationelement connection end 211D and which is connected to an outerperipheral surface 101D of thevibration element 10D does not form a sharp corner, and a rectangular will be obtained if connecting each vertexes. In other words, different with the waveforms in above three embodiments which are formed as sinusoidal waveform, the waveform in this preferred embodiment is about square wave. It is expected that each above vertexes can be connected to form a trapezoid. These structures all form a groove around thevibration element 10D, so that a series of concave-shaped structure forms an undulating wave-shaped structure. - It is worth mentioning that the
vibration unit 100D in this embodiment of the present invention is obtained by a transform of thevibration unit 100C in the previous example. In other words, in the multiple sets of the connectingribs 22C of theelastic suspension edge 20C of thevibration unit 100C, when each set of the connecting ribs 22 comprises two adjacenttop connecting rib 221C and twobottom connecting ribs 222C adjacent to the two top connectingribs 221C, thevibration unit 100D in the embodiment of the present invention is obtained. - It is worth mentioning that, similarly, two ends of the
elastic suspension edge 20D which are respectively connected to thevibration element 10D and the supportingframe 30D have a same or different connection configuration. As shown inFig. 26 , the vibrationelement connection end 211D which is an inner edge of the wave-shapedretaining sections 21D and which is connected to the outerperipheral surface 101D of thevibration element 10D can be a poly-line comprising different line segments, while the supportingframe connection end 212D which is an outer edge of the wave-shapedretaining sections 21D and which is connected to the interiorperipheral surface 301D of the supportingframe 30D only forms one line, so that the connecting strength of theelastic suspension edge 20D and thevibration element 10D is bigger than the connecting strength of theelastic suspension edge 20D and the supportingframe 30D. - One skilled in the art will understand that the embodiment of the present invention as shown in the drawings and described above is exemplary only and not intended to be limiting.
- It will thus be seen that the objects of the present invention have been fully and effectively accomplished. The embodiments have been shown and described for the purposes of illustrating the functional and structural principles of the present invention and is subject to change without departure from such principles. Therefore, this invention includes all modifications encompassed within the scope of the following claims.
Claims (15)
- A wave-shaped suspension edge structure for a speaker which comprises a vibration element (10A) and a supporting frame (30A), wherein said wave-shaped suspension edge structure comprises an elastic suspension edge (20A) arranged for extending around said vibration element (10A) and extending between said vibration element (10A) and said supporting frame (30A), wherein said elastic suspension edge comprises a plurality of wave-shaped retaining sections (21A) forming a wave-shaped structure around said vibration element (10A) along a circumferential direction so as to ensure that a movement direction of said vibration element (10A) is kept along an axial direction and to prevent said vibration element (10A) from shaking and deviating,
characterized in that a ripple amplitude of each of said wave-shaped retaining sections (21A) is decreasing from an outer peripheral surface (101A) of said vibration element (10A) to an interior peripheral surface (301A) of said supporting frame (30A). - The wave-shaped suspension edge structure, as recited in claim 1, wherein a groove (203A) is formed between two adjacent wave-shaped retaining sections (21A) so as to form said wave-shaped structure, wherein the shape of said wave-shaped structure is selected from the group consisting of sinusoidal waveform, triangular waveform and saw-tooth waveform.
- The wave-shaped suspension edge structure, as recited in claim 1, wherein each of said wave-shaped retaining sections (21A) is perpendicularly extended from an outer peripheral surface (101A) of said vibration element (10A) to an interior peripheral surface (301A) of said supporting frame (30A).
- The wave-shaped suspension edge structure, as recited in claim 1, wherein each of said wave-shaped retaining sections (21A) which is configured to be connected to said vibration element (10A) has a sinusoidal waveform shaped inner edge, wherein each of said wave-shaped retaining sections (21A) which is configured to be connected to said supporting frame (30A) has an outer edge which is an arc-shape along a circumferential direction or a sinusoidal-waveform-shape.
- The wave-shaped suspension edge structure, as recited in claim 1, wherein an inner edge of each of said wave-shaped retaining sections (21A) which is configured to be connected to said vibration element (10A) has a shape selected from the group consisting of sinusoidal waveform, triangular waveform and saw-tooth waveform, wherein each of said wave-shaped retaining sections (21A) which is configured to be connected to said supporting frame (30A) has an outer edge which is arc-shaped along a circumferential direction or has a shape selected from the group consisting of sinusoidal waveform, triangular waveform and saw-tooth waveform.
- The wave-shaped suspension edge structure, as recited in claim 1, wherein each vibration element connection end (211A) of each of said wave-shaped retaining sections (21A), which is configured to be connected to said vibration element (10A), comprises two portions forming one angle therebetween, wherein supporting frame connection ends (212A) of said wave-shaped retaining sections (21A), which are configured to be connected with said supporting frame (30A), are configured to be connected to each other to form a ring-shaped outer edge coaxial with said vibration element (10A).
- The wave-shaped suspension edge structure, as recited in claim 1, wherein wave crests of said wave-shaped retaining sections (21A) have lower height than a level surface of an outer surface of said vibration element (10A).
- The wave-shaped suspension edge structure, as recited in claim 1, wherein each of wave crests of at least one of said wave-shaped retaining sections (21A) has a height higher than a level surface of an outer surface of said vibration element (10A).
- The wave-shaped suspension edge structure, as recited in claim 1, wherein said wave-shaped retaining sections (21A) are arranged symmetrically relative to a center of said vibration element (10A).
- A vibration unit (100A) comprising a vibration element (10A), a supporting frame (30A) and a wave-shaped suspension edge structure according to any one of the claims 1 to 9.
- The vibration unit (100A), as recited in claim 10,wherein said vibration element (10A) has a shape which is selected from the group consisting of circular, oval, rectangle, and polygon, wherein a number of said wave-shaped retaining sections (21A) is 2-200 and the ripple amplitude of each wave-shaped retaining section (21A) is 1-500 mm, wherein the area size of said vibration element (10A) is 0.005-0.2 m2.
- The vibration unit (100A), as recited in claim 10, wherein said vibration element (10A) comprises a vibration weighted element (11) and a coating layer (12) coated on said vibration weighted element (11), wherein said coating layer (12) is made of the same material as said elastic suspension edge (20A).
- The vibration unit (100A), as recited in claim 10, wherein said elastic suspension edge (20A) is bonded with said supporting frame (30A) and said vibration element (10A), wherein said vibration unit (100A) is connected to a voice coil (110A) coupling with a magnetic coil system (120A) so as to form a loudspeaker.
- The vibration unit (100A), as recited in claim 10, wherein said vibration unit (100A) is a passive vibrating plate sharing a vibration cavity (1200A') with at least one main vibration speaker (1100A'), wherein said main vibration speaker (1100A') vibrates to produce sounds in response to an input of audio signals, wherein said vibration unit (100A) is driven to vibrate to produce an auxiliary sound by means of the air pressure changes within said vibration cavity (1200A'), wherein said main vibration speaker (1100A') and said vibration unit (100A) are arranged side by side.
- The vibration unit (100A), as recited in claim 10, wherein said vibration unit (100A) is a passive vibrating plate sharing a vibration cavity (1200A') with at least one main vibration speaker (1100A'), wherein said main vibration speaker (1100A') vibrates to produce sounds in response to an input of audio signals, wherein said vibration unit (100A) is driven to vibrate to produce an auxiliary sound by means of the air pressure changes within said vibration cavity (1200A'), wherein said main vibration speaker (1100A') and said vibration unit (100A) are coaxial arranged back-to-back.
Applications Claiming Priority (3)
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CN201410019799 | 2014-01-16 | ||
CN201410328141.6A CN104796825B (en) | 2014-01-16 | 2014-07-10 | A kind of outstanding side structure of waveform |
PCT/CN2015/070682 WO2015106685A1 (en) | 2014-01-16 | 2015-01-14 | Wave-shaped suspension edge structure and vibration unit |
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EP3096537A1 EP3096537A1 (en) | 2016-11-23 |
EP3096537A4 EP3096537A4 (en) | 2017-10-18 |
EP3096537B1 true EP3096537B1 (en) | 2019-10-16 |
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EP (1) | EP3096537B1 (en) |
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CN207340149U (en) * | 2016-04-01 | 2018-05-08 | 宁波升亚电子有限公司 | Comprehensive sound type speaker |
CN207039882U (en) * | 2016-05-18 | 2018-02-23 | 宁波升亚电子有限公司 | Radiator and double suspension side loudspeaker and audio amplifier |
CN109788408B (en) * | 2017-11-10 | 2023-08-22 | 惠州迪芬尼声学科技股份有限公司 | Hanging edge structure of loudspeaker |
CN111920394A (en) * | 2020-06-23 | 2020-11-13 | 泰安市泰医医疗器械有限公司 | Air bag type pulse probe and manufacturing and using method thereof |
WO2023108466A1 (en) * | 2021-12-15 | 2023-06-22 | Sonos, Inc. | Suspension elements for playback devices |
WO2023274399A1 (en) * | 2021-07-02 | 2023-01-05 | Sonos, Inc. | Systems and methods for stabilizing playback device |
Family Cites Families (9)
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GB368926A (en) * | 1931-01-29 | 1932-03-17 | Victor Talking Machine Co | Improvements in acoustic diaphragms |
US2442791A (en) * | 1945-09-07 | 1948-06-08 | Bell Telephone Labor Inc | Acoustic device |
JPS5434589Y2 (en) * | 1978-02-23 | 1979-10-23 | ||
GB2374753B (en) * | 2001-01-29 | 2004-12-22 | Goodmans Loudspeakers Ltd | Loudspeaker suspension |
JP5088526B2 (en) * | 2005-04-18 | 2012-12-05 | ソニー株式会社 | Jet generator and electronic device |
CN201403189Y (en) * | 2009-04-17 | 2010-02-10 | 天津市中环电子信息集团有限公司 | Composite cone of ultra-thin speaker |
CN201499297U (en) * | 2009-09-24 | 2010-06-02 | 无锡杰夫电声有限公司 | Thin speaker without using positioning support chip |
CN202135035U (en) * | 2011-06-27 | 2012-02-01 | 歌尔声学股份有限公司 | Horizontally vibration motor |
CN102984631B (en) * | 2012-11-14 | 2015-12-09 | 宁波升亚电子有限公司 | Audio sheet, the loud speaker be made up of audio sheet, audio amplifier and preparation technology thereof |
-
2014
- 2014-07-10 CN CN201410328141.6A patent/CN104796825B/en active Active
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2015
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WO2015106685A1 (en) | 2015-07-23 |
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EP3096537A1 (en) | 2016-11-23 |
CN104796825B (en) | 2019-07-12 |
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