This disclosure relates generally to acoustic receivers and more specifically to shock protection mechanisms implemented in balanced armature receivers.
Many hearing instruments such as hearing aids, earphones, and personal audio headsets, among other devices include one or more balanced armature receivers, also referred to herein as “acoustic receivers” or “receivers”. Such receivers generally comprise a case or housing containing a diaphragm that divides an interior of the housing into front and back volumes. A motor located in the back volume includes an electrical coil with a passage through which an armature (also called a reed) is disposed. The armature has a stationary end fixed to a yoke and another end movably disposed between magnets supported by the yoke. A drive rod or other link couples the armature to the diaphragm. In operation, an electrical signal applied to the electrical coil causes the armature to vibrate between the magnets. The vibrating armature moves the diaphragm, resulting in emission of sound from an aperture in the front volume of the housing. However, external forces or shocks that are applied to the receiver may damage the internal components such as the armature, thereby reducing performance of the receiver.
Those of ordinary skill in the art will appreciate that elements in the figures are illustrated for simplicity and clarity. It will be further appreciated that certain actions or steps may be described or depicted in a particular order of occurrence while those of ordinary skill in the art will understand that such specificity with respect to sequence is not actually required unless a particular order is specifically indicated. It will also be understood that the terms and expressions used herein have meanings accorded to such terms and expressions by those having ordinary skill in the art except where specific meanings have otherwise been set forth herein.
The present disclosure pertains to balanced armature receivers in one of numerous different implementations. Such receivers are typically integrated in hearing aids such as behind-the-ear (BTE) devices with a portion that extends into or on the ear, in-the-canal (ITC) or partially in the ear canal devices, receiver-in-canal (RIC) devices, as well as headsets, wired or wireless in-the-ear (ITE) earbuds or earpieces, among other devices that produce an acoustic output signal in response to an electrical input signal and intended are for use on, in, or in close proximity to a user's ear.
In one implementation, the balanced armature receiver includes a yoke retaining first and second permanent magnets in spaced-apart relation, a coil assembly having a coil tunnel, and an armature having a portion coupled to the yoke, a movable portion that extends through the coil tunnel, and an end portion located at least partially between the magnets. The end portion is free to deflect between the magnets in response to an excitation signal applied to the coil assembly. The receiver also includes a stationary protrusion extending from a stationary portion of the receiver toward the movable portion of the armature, and a movable protrusion extending from the movable portion of the armature toward the stationary portion of the receiver. The stationary and movable protrusions are offset laterally. In some embodiments according to the above implementation, the stationary and movable protrusions are offset longitudinally. In some embodiments according to the above implementation, the stationary and movable protrusions are offset both laterally and longitudinally.
In some embodiments, the stationary portion of the receiver is the coil assembly or one of the magnets. In some examples of such embodiments, the coil assembly has a first end and a second end adjacent to the magnets. The second end of the coil assembly is opposite the first end of the coil assembly, and the stationary protrusion extends from a surface of the coil assembly proximate the first end of the coil assembly. In some other examples of such embodiments, the coil assembly includes a coil, an insulator disposed on the coil, and an epoxy on a surface of the coil. The epoxy forms the stationary protrusion.
In yet other examples of the embodiments, the coil assembly includes a coil and a bobbin, where the bobbin includes a coil support member having the tunnel extending between a first end and a second end of the coil support member, a first flange extending from the coil support member, and a second flange extending from the coil support member and spaced apart from the first flange. The coil is disposed about the coil support member between the first and second flanges, and the bobbin forms the stationary protrusion. In some examples, the stationary protrusion is formed proximate the first flange and the second flange is nearer the magnets than the first flange.
In some examples of the embodiments, the coil assembly includes a coil and a movement-restricting spacer disposed on one end of the coil. The spacer forms the stationary protrusion. In some other examples of the embodiments, the magnets include a first end and a second end adjacent to the coil assembly. The second end of the magnets are opposite the first end of the magnets. The stationary protrusion extends from a surface of the magnets proximate the second end of the magnets.
In some embodiments, the receiver includes a plurality of stationary protrusions extending from the stationary portion of the receiver toward the movable portion. In some examples of the embodiments, the plurality of stationary protrusions are offset laterally or longitudinally from each other.
In some embodiments, the receiver includes a plurality of movable protrusions extending from the movable portion toward the stationary portion of the receiver. In some examples of the embodiments, the plurality of movable protrusions are offset laterally or longitudinally from each other. In some examples of the embodiments, the plurality of movable protrusions include a first movable protrusion proximate the coil assembly and a second movable protrusion proximate one of the magnets.
In some embodiments, the receiver includes a plurality of stationary protrusions extending from the stationary portion of the receiver toward the movable portion as well as first and second movable protrusions positioned on opposing sides of the movable portion of the armature. In some examples, the plurality of stationary protrusions include first and second pairs of stationary protrusions positioned adjacent opposing sides of the movable portion of the armature. In some other examples, the plurality of stationary protrusions include first and second stationary protrusions positioned adjacent opposing sides of the movable portion of the armature.
The receiver also has at least one stationary protrusion 120 and at least one movable protrusion 122 that extend from various parts of the receiver. For example, the stationary protrusion (or protrusions) extends from a stationary portion of the receiver toward the movable portion 116 of the armature. The stationary portion of the receiver may refer to a surface or section of any suitable stationary subcomponent of the receiver. In some examples, the stationary portion of the receiver is the coil assembly. In some examples, the stationary portion is one of the magnets. In other examples, the stationary portion is part of a spacer, also known as a “snubber.”
The movable protrusion (or protrusions) extends from the movable portion of the armature toward the stationary portion of the receiver from which the stationary protrusions extend. In some examples, the stationary protrusions may be offset laterally with respect to the movable protrusions, that is, the stationary protrusions and the movable protrusions are not aligned with respect to an axis that extends perpendicularly to a direction in which the armature extends. In some examples, the stationary protrusions may be additionally or alternatively offset longitudinally with respect to the movable protrusions, that is, the stationary protrusions and the movable protrusions are not aligned with respect to an axis that extends parallel to the direction in which the armature extends.
In some examples, any one or more of the stationary or movable protrusions may be formed by applying a mechanical force to the receiver component, for example the movable portion of the armature, from which the protrusions are configured to extend. In some examples, any one or more of the stationary or movable protrusions may be formed by attaching or applying a polymeric material, for example epoxy, on a surface of the receiver component from which the protrusions are configured to extend. In some examples, the stationary protrusions and the movable protrusions are formed using a solid material such as plastic (e.g., when the epoxy or other suitable polymeric material solidifies after being applied to a surface) or metal (e.g., when the stationary protrusions are formed by applying pressure or force to deform a portion of the movable portion of the armature). In some examples, the stationary protrusions or the movable protrusions are formed using a compliant, flexible, or elastic material.
The receiver has a housing 134 (e.g., a metal or plastic casing) with a sound port 136. A diaphragm 138 (which may include a movable paddle and a flexible membrane, for example) separates an internal volume of the housing into a back volume 140 and a front volume 142 such that the front volume is acoustically coupled with the sound port and the back volume at least partially contains a receiver motor 144. The motor 144 may be fastened to a bottom wall portion 146 of the housing. The housing may also have a sidewall portion 147 extending from the bottom wall portion 146 and surrounding the motor.
The bobbin includes a coil support member 128 having the coil tunnel 110 extending between the two ends of the coil support member, and two flanges 130 and 132. The first flange 130 extends from the coil support member at a first location of the coil support member, and the second flange 132 extends from the coil support member at another, second location of the coil support member different from the first location such that the two flanges are spaced apart. The coil 124 is disposed about the coil support member 128 between the first flange and the second flange, and the bobbin 126 forms the stationary protrusions 120. The receiver motor also includes a link or drive rod 148 that interconnects the diaphragm 138 and the end portion 118 of the armature.
The bobbin 126 includes conductive pins 150 extending therefrom. The housing 134 further includes an opening (not shown) in the sidewall portion 147 through which a portion of each of the conductive pins 150 extends or protrudes to an external side of the housing, which is where a terminal board 152 may be located. In some examples, the conductive pins, or at least a portion of the conductive pins, may be electrically coupled with the terminal board via a solder 154 which also fixes the conductive pins relative to the terminal board.
In some of the examples where the bobbin is implemented, the bobbin defines the stationary protrusions 120 as well as the coil tunnel 110. That is, the coil support member and/or the flange(s) may define the location and configuration of the stationary protrusions, and the coil support member defines the shape and size of the coil tunnel. For example, the stationary protrusion may be formed proximate the first flange, and the second flange is nearer the magnets than the first flange. In examples where the bobbin is not implemented, other components may define the protrusions and the coil tunnel, as explained herein.
In some embodiments, as illustrated, the housing 134 further includes a sound tube or nozzle 156 acoustically coupled with the sound port 136. In some examples, the sound tube or nozzle extends longitudinally from the housing on an opposite side from the terminal board or the opening through which the conductive pins at least partially extend. In some examples, the sound tube or nozzle is located on some other side of the housing.
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In some examples, the bottom wall portion 146 of the housing may include an adhesive 1302 to attach the coil to the housing. Additionally or alternatively, an adhesive 1304 may be disposed between the coil and the magnets 104, 106 and/or the yoke 102 such that the coil can be attached to an end of the magnets and/or the yoke. The adhesive may be glue, bond, or epoxy, among others, which facilitates fixedly attaching the coil to the bottom wall portion of the housing so as to fix the position of the coil in the housing and align the coil tunnel with the space between the magnets In some examples, the adhesive may be made of an electrically insulative material.
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The stationary and movable protrusions 120, 122 facilitate shock absorption or shock protection in response to an external shock or force applied to the receiver 100, for example during manufacture or operation of the receiver. The protrusions may protect the components of the receiver, such as armature 112, link 148, or diaphragm 138, from damages caused by a sudden or extreme deflection of the movable portion 116 of the armature caused by such external force by using the protrusions to reduce the degree of deflection of the movable portion.
In some examples, the protrusions may limit the amount of strain that a reed or armature undergoes by limiting the movement of the reed or armature. The limited movement, therefore, reduces the deflection of the reed or armature, which reduces the amount of strain experienced in the reed. The reduced displacement and strain also reduce the bending stress in the reed and decrease the likelihood or capacity of the reed to plastically deform in response to excitation experienced from an external acceleration. The protrusion may be solid, flexible, or both (that is, partially solid and partially flexible, for example). In some examples, the reduced motion of the reed or armature may reduce the proximity that the movable portion of the reed or armature may approach the magnets. That is, by maintaining the movable portion at a predetermined distance from the magnets, the magnetization from the magnets may have less of an effect the movement of the movable portion. For example, in some instances, the attractive force of the magnet may either cause acceleration in the movable portion of the reed or armature at a point of impact, restrain the movable portion from deflecting away from the magnet, or both, which may allow for increased damage to the reed in response to excitation.
In some examples, the protrusions may be positioned as far away as possible from the line of symmetry of the armature (for example, at or near the side edges of the armature, between which the line of symmetry may be located) given the structural limitation of the armature. Positioning the protrusions further outward with respect to the line of symmetry may improve the effect as explained herein that is offered by the protrusions, for example in case of the receiver experiencing shock from the side of the receiver housing. In some examples where there are protrusions of different sizes, the relatively smaller protrusions may be positioned further apart from the line of symmetry than the relatively larger protrusions. The smaller protrusions may be controlled with greater accuracy or precision than the larger protrusions. In some examples, additional protrusions may be positioned along the armature for additional protection for the armature, such as from a greater variety of shock applied from different directions as well as the different amplitudes of shock that the armature may experience.
In some examples, the protrusions are also beneficial as positioning markers during assembly or manufacture, such that the positions of the other components of the receiver (e.g., magnets, coil, bobbin, etc.) may be determined or confirmed with respect to the protrusions that are located on the armature. Alternatively, or additionally, the protrusions may be used as visual alignment feature (which may be detected using high-precision sensors or detectors) to facilitate centering of the other components during assembly or manufacture.
While the present disclosure and what is presently considered to be the best mode thereof has been described in a manner that establishes possession by the inventors and that enables those of ordinary skill in the art to make and use the same, it will be understood and appreciated that there are many equivalents to the exemplary embodiments disclosed herein and that myriad modifications and variations may be made thereto without departing from the scope and spirit of the disclosure, which is to be limited not by the exemplary embodiments but by the appended claims.
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