The present invention relates to a speaker unit.
Speaker units are well known in the prior art, such as speaker transducers comprising a cone shape speaker membrane and a membrane driver or actuator coaxially arranged with respect to the speaker membrane at a back side thereof. Planar type speaker units are also known in the art, wherein the speaker transducer comprise a planar speaker membrane and a plurality of membrane drivers arranged along a surface of the speaker membrane. Although the well-known coaxial cone shaped speaker transducers allow for high performance and fidelity, they are less suitable for smaller loud speaker systems due to the coaxial arrangement of the speaker membrane and membrane driver. Planar type speaker transducers do allow for flatter loudspeaker designs because of the substantially flat speaker membrane.
International patent publication WO2019/117706 discloses a speaker device having a frame, two opposite directed diaphragms, and two speaker drivers, each having at least one magnetic driver for driving the two opposite directed diaphragms in operation. A speaker damper is associated with each of the two opposite directed diaphragms, and has a coil bracket arranged to be driven by the associated at least one magnetic driver, a diaphragm connection member arranged to fixedly attach the diaphragm to the speaker damper, and a damper frame connection member arranged to fixate the speaker damper to the frame. The speaker damper further comprises a damper leg member arranged between the diaphragm connection member and the damper frame connection member.
The present invention seeks to provide a speaker unit having small dimensions, yet provides a linear response characteristic.
A speaker unit is provided which includes a speaker frame with a major front surface and a major back surface, two opposing (sound producing) membranes arranged in the major front surface and the major back surface, respectively, each being arranged to move up and down along a main speaker axis (perpendicular to major front and back surfaces of speaker). At least two drive units are provided for each of the two opposing membranes, each drive unit comprising a driver static part and a driver moving part, the driver moving part being fixedly connected to the associated one of the two opposing membranes. Each of the two opposing membranes are provided with a sealing edge suspension connected to a perimeter of the associated membrane and to the major front surface and major back surface, respectively, further comprising, for each driver moving part, a spider arm suspension connected on one side to the associated driver moving part and on another side to the speaker frame for suspending the driver moving part to the speaker frame in a flexible manner, wherein the sealing edge suspension is at least partially positioned above the associated drive units when viewed in a direction parallel to the main speaker axis. This positioning of the sealing edge suspension relative to the drive unit, and the associated spider arm suspension, allows the two opposing membranes to move along the main speaker axis without any chance of interference or blocking by other (internal) components of the speaker unit.
The present invention will be discussed in more detail below, with reference to the attached drawings, in which
The present invention embodiments relate to a loudspeaker unit having an improved compactness of architecture using a dual membrane driver architecture, while keeping the membrane movement as linear as possible. Such loudspeaker unit could be a speaker device as described in the international patent publication WO2019/117706, filed 24 Apr. 2018 and titled Distributed Transducer Suspension Cones (DTSC), of the same inventors as the present application, which is incorporated herein by reference.
For improved linearity and air tight sealing a second suspension element is provided in embodiments, as discussed in detail below with reference to a particular embodiment. The arrangement of the membranes 2, 2′, drive units 3, 3′ and suspension components allow free movement of the membranes 2, 2′ without collisions with any internal speaker unit components.
The speaker unit 1 has a speaker frame 4 with a major front surface and a major back surface, and two opposing (sound producing) membranes 2, 2′ arranged in the major front surface and the major back surface, respectively, each being arranged to move up and down along a main speaker axis A. The major speaker axis in this embodiment is perpendicular to the major front and back surfaces of the speaker unit 1. At least two drive units 3, 3′ for each of the two opposing membranes 2, 2′ are provided, each drive unit 3, 3′ comprising a driver static part (in this embodiment a magnet stack 6, 6′) and a driver moving part (in this embodiment a voice coil 7, 7′), the driver moving part 7, 7′ being fixedly connected to the associated one of the two opposing membranes 2, 2′ (e.g. using a connection member 2a as shown in the embodiments in
In some embodiments, the sealing edge suspension 8, 8′ is at least partially positioned above the associated drive units 3, 3′ when viewed in a direction parallel to the main speaker axis A.
To create a compact transducer for a speaker unit, it is required to make the stack of necessary components as low as possible. In electrodynamic transducers, several components are necessary such as coil(s), magnet(s), suspension(s), membrane(s), a frame to hold all components. In patent publication WO2020/160791 (of the same applicant as the present application), a cross shaped bellows suspension is disclosed. This bellows suspension shape has the benefit of allowing the air tight sealing suspension to stay on the inner perimeter of the membranes and spring-like suspension. A disadvantage of this cross-shape bellows structure is the suboptimal use of in-bounding-box surface area. To make use of the frontal surface of the driver as efficiently as possible, the orientation of the air tight sealing suspension is merged with the position of the drive units. The arrangement of drive units 3, 3′ and suspensions 8, 8′; 9, 9′ provides sufficient clearance for high excursion linear membrane movement without risk of collisions of internal components of the speaker unit 1.
In the embodiment described with reference to the drawings, the driver static part 6, 6′ is a magnet stack 6, 6′ and the driver moving part 7, 7′ is a voice coil 7, 7′. The voice coil 7, 7′ is moving relative to the magnet stack 6, 6′ which is fixedly attached to the speaker frame 4. In further embodiments, the drive unit 3 may be kinematic reversed, having a driver static part 6, 6′ formed by a voice coil fixedly attached to the speaker frame 4, and a driver moving part 7, 7′ formed by a magnet or a stack of magnets fixedly attached to an associated one of the opposing membranes 2, 2′.
In further embodiments, for each drive unit 3, 3′ the driver moving part 7, 7′ is positioned at a minimum drive unit distance rd from the main speaker axis A, and the sealing edge suspension 8, 8′ has a ring shape with a smallest radius rmin which is larger than the minimum drive unit distance rd.
These dimensions are also shown in the top projection view of the speaker unit of
The embodiments can also be defined using a further feature, wherein the sealing edge suspension 8, 8′ has a ring shape with a largest radius rmin+ds, the associated driver static parts 6, 6′ being positioned on a magnet radius rm from the main speaker axis A, wherein the largest radius rmin+ds is larger than the magnet radius rm. This ensures the sealing edge suspension 8, 8′ is overlapping the magnet stacks 6, 6′ when viewed along the major speaker axis A.
Note that in the embodiments shown, the spider arm suspension 9, 9′ has a widest diameter which is less than a maximum diameter dm of the drive unit 3, 3′. As a result of this, in the embodiments, the drive unit 3, 3′ and its directly associated components (i.e. spider arm suspension 9, 9′) has a circumference when viewed along the major speaker axis A with the diameter rm positioned at a minimum drive unit distance rd. The diameter of the voice coil 7, 7′ is determining the volume within speaker frame 4 which is free of any interfering components.
As an alternative, embodiments may also be formulated where the sealing edge suspension 8, 8′ has a substantially ring shaped form, wherein a projection of the ring shaped form on the major front surface along a direction parallel to the main speaker axis A at least partially overlaps with projections of the associated drive units 3, 3′ on the major front surface along a direction parallel to the main speaker axis A. This is illustrated most clearly in the projection view of
As shown most clearly in the cross sectional views of
In the speaker unit 1, the membranes 2, 2′ are brought in motion by the drive units 3, 3′. The membranes 2, 2′ need to move in a linear motion, therefore the spider arm suspensions 9, 9′ and the sealing edge suspensions 8, 8′ are attached to each membrane 2, 2′. The spider suspension 9, 9′ is attached to the membrane 2, 2′ and the voice coil 7, 7′, and positioned underneath the voice coil 7, 7′ (taking the outward excursion direction of membrane 2 as facing up). The sealing edge suspension 8, 8′ is attached to the membrane 2, 2′ at the periphery thereof, and positioned above the voice coil 7, 7′. To make the frontal face (major front surface) of the speaker unit 1 as compact as possible, the middle of the sealing edge suspension 8, 8′, i.e. the apex of the arc shaped cross section is situated above the drive unit 3, 3′. The apex is the middle of the arc shaped cross section, in other words equal to the outer diameter of the bending part (arc shaped cross section) of the sealing edge suspension 8, 8′, plus the inner diameter of the bending part, divided by two. As a result, when the membrane 2, 2′ is in motion, the arc shaped cross section of the sealing edge suspension 8, 8′ will bend over the magnet stack 6, 6′ of the drive unit 3, 3′(as the voice coil 7, 7′ is moving inward in the speaker frame 4. Because of the positioning of the sealing edge suspension 8, 8′ and the drive unit 3, 3, the membrane 2, 2′ is able to move within the speaker frame 4 without collisions with other components of the speaker unit 1.
In an even further embodiment, a projection on the major front surface of the spider arm suspension 9, 9′ (see top projection view of
As discussed above, each membrane 2, 2′ comprises membrane connection elements 2a, 2a′ connecting the membrane 2, 2′ to an associated driver moving part 7, 7′. The connection element 2a, 2a′ may form an integrated element of each membrane 2, 2′, or alternatively, it may be a separate element connected to the voice coil 7, 7′ and the membrane 2, 2′. In order to ensure proper operation, each membrane connection element 2a, 2a′ is positioned at a predetermined distance from the other one of the opposing membranes 2, 2′ when the opposing membranes 2, 2′ are at a minimum distance (amin) of each other during operation (see
In the exemplary embodiments shown in and described with reference to
In even further embodiments, the two opposing membranes 2, 2′ each comprise a frontal sound producing surface with a conical surface, a frusto-conical surface, or a flat surface. In the embodiments shown in the figures and discussed above, the membranes 2, 2′ have a frusto-conical shape, with a flat surface in the middle of the conus shape. The other surface shapes are also possible to be implemented, with the proper adaption of possibly interfering components of the speaker unit 1, as discussed above for all other exemplary embodiments.
The present invention has been described above with reference to a number of exemplary embodiments as shown in the drawings. Modifications and alternative implementations of some parts or elements are possible, and are included in the scope of protection as defined in the appended claims.
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20070194635 | Miura | Aug 2007 | A1 |
20100172535 | Huang | Jul 2010 | A1 |
20110075880 | Kamimura | Mar 2011 | A1 |
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Number | Date | Country |
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WO-2019086357 | May 2019 | WO |
WO-2019117706 | Jun 2019 | WO |