The present invention relates to an ear piece. The invention more particularly relates to an ear piece for a hearing aid. The invention further relates to a hearing aid with an ear plug with a flexible ear tip. The invention also relates to a communications device comprising an ear piece. The invention, more specifically, relates to a flexible ear tip for an In-the-Ear style hearing aid, for a Receiver-In-The-Ear style hearing aid, for a Behind-The-Ear (BTE) style hearing aid, or for a communications device.
Within the context of the present disclosure an ear piece is understood as a plug or a similar structure suitable for insertion into a human ear and adapted for conveying acoustic power into the ear canal and for shielding the ear canal against sound from the surroundings. The acoustic power is typically derived from an electro-acoustic transducer, which may be arranged in the ear piece or spaced from the ear piece. The acoustic signal may be for the purpose of enhancing hearing, for communication or for amusement, e.g. for playing music etc.
Within the context of the present disclosure a hearing aid can be understood as a small, battery-powered, microelectronic device designed to be worn behind or in the human ear by a hearing-impaired user. A hearing aid comprises one or more microphones, a battery, a microelectronic circuit comprising a signal processor adapted to provide amplification tailored to meet the needs of the user, and an acoustic output transducer (in the hearing aid parlance often referred to as the receiver). The signal processor is preferably a digital signal processor. The hearing aid is enclosed in a casing suitable for fitting behind or in a human ear.
Hearing aids are sometimes classified to styles, notably BTE (Behind-The-Ear) for a hearing aid having electronics and speaker in a capsule fitting behind the ear and with a sound tube guiding the acoustic power to an ear piece, RITE (Receiver-In-The-Ear) for a hearing aid having electronics in a capsule fitting behind the ear, which is connected by a cable to an ear piece housing the output transducer, and ITE (In-The-Ear) for an integrated capsule fitting in the ear, such as in the concha or the canal. Either of these styles of hearing aids need some kind of ear tip for retaining the sound output opening correctly in the mouth of the ear canal.
Prior to use, the hearing aid is adjusted by a hearing aid fitter according to a prescription. The prescription is based on a hearing test, the result of which is expressed in an audiogram depicting the performance of the hearing-impaired user's unaided hearing. The prescription is developed to reach a setting where the hearing aid will alleviate a hearing loss by amplifying sound at frequencies in those parts of the audible frequency range where the user suffers a hearing deficit.
The acoustic output is produced by the output transducer and discharged into the ear canal through a conduit or an opening. The ear tip serves to maintain the conduit in position so as to prevent it from becoming dislodged, and to prevent the opening from being blocked by getting in contact with the walls in the ear canal. The ear tip may feature particular measures at the sound output, e.g. grids or a convoluted shape, serving to trap or block ingress of ear wax and humidity into the internals of the transducer, while keeping open the acoustic conduit to the extent possible.
The ear tip should further provide acoustic insulation between the inner part of the ear canal and the surroundings. However, for various reasons (bypass for enabling listening to un-amplified sound, pressure equalization, humidity control and general user comfort) a vent may be included, normally in the form of a passage deliberately incorporated in the plug. Ideally the vent should be carefully calibrated to the specific user's needs. A vent inevitably creates an acoustic leak, with the attendant risk of loss of amplified sound power and of amplified sound looping back to the microphone of the hearing aid, where it may be further amplified, potentially leading to an unstable feedback situation.
Users with a mild hearing loss and a correspondingly low gain setting, may favor a large vent to relieve the pressure build-up by own-voice speaking and to enable them to listen to the direct sound, which is useful if they retain good hearing acuity in part of the frequency range. Users with a profound hearing loss and a correspondingly high gain setting may favor a small vent, or maybe a closed one, to avoid unstable feedback and to avoid loss of sound power, and as any problems with excessive own-voice sound build-up can, in case of a high gain setting, be handled satisfactorily by appropriate automatic gain adjustments.
As the vent is normally fixed once the ear plug has been made, a design choice regarding the length and lumen of the passage has to be made for the specific user to strike the optimal balance between these considerations. State-of-the-art hearing aids will then be adjusted taking into consideration the specific vent size and its implications on feedback gain limit, loss of sound power, leakage of sound to bystanders, and mixing direct sound with amplified sound.
WO-A1-2006094502 discloses an earplug for a hearing aid comprising a main body part having a sound output opening. The earplug also has a collar, adapted to engage the wall of an ear canal and surrounding the main body part.
U.S. Pat. No. 3,935,401 provides an earpiece having a tubular hub with a flange on an end of the hub about a central passage, comprising radiating ribs which are mutually separated by radiating slots or by webs.
EP-A1-1594340 provides a flexible ear mold fitting comprising a base and a sidewall that is attached to the base and has an edge that extends substantially from the base to an opening of the earpiece.
US-B2-9094756 provides an ear piece including a compliant element operative to be inserted in the user's ear such that the compliant element deforms to retain the ear piece in the user's ear. The compliant element may include an outer portion folded over the ear piece housing.
U.S. Pat. No. 7,602,933 provides an ear piece device comprising a generally cone-shaped article made of pliable material dimensioned for fitting the ear canal of a user. A canal may extend through the ear piece to provide for communication between a person's inner ear and an environment outside the person's ear. The ear piece has a plurality of fold lines provided to facilitate the reversible collapsing of the cone into a star-like configuration when sufficient outside pressure is applied thereto.
WO-A2-02078392 provides a method of making a hearing aid housing with a shell, which is customized to an ear canal and further provided with a tightening contour, which at least partially encircles the shell.
WO-A1-2014146702 provides a hearing aid comprising a behind-the-ear part, an ear canal part and a cable. The cable is attached to a side wall of the ear canal part and is extending from this side wall in an angle to the axis between 20-70 degrees. The lateral end of the ear canal part may abut the outer ear, at the tragus part, while the cable abuts the outer ear at the concha, the tragus or the helix. This achieves a very stable positioning of the ear canal part, and prevents lateral migration of the ear canal part during chewing or talking.
EP-A2-2192789 provides an earpiece having a cap portion that has cutting portions formed in a direction of a through hole of a main unit. The cutting portions of the earpiece make through holes in the cap portion.
The human ear canal (the external auditory meatus) extends from the aperture (opening) of the ear canal to the tympanic membrane (eardrum). From the medial end, near the eardrum, it gradually flares out towards the lateral outer meatus. As seen from above it is slightly S-shaped. The cross-section is oval and slightly pointed downwards. Part of the wall is subject to movements linked to movements of the jaw bone. However, there is wide variability in size and shape among individuals. Some researchers report that the major axis tends to twist toward the horizontal as it approaches the tympanum, in the bony region of the ear canal. However, based on studies on a large number of hearing aid users, the inventors have found that the major axis of the oval can assume practically any attitude from vertical to horizontal.
Within the field of ear pieces it is standard practice to provide a selection of sizes and, to a lesser extent, shapes. Non-customized pieces are generally referred to as instant-fit.
For obtaining a close fit it is also a standard practice to provide a customized shape (custom fit) based on an impression of an individual ear canal. Providing a custom fit ear piece necessarily requires a more complicated process than providing an instant-fit ear piece. Even so, a custom fit ear plug may not answer all problems, as the ear canal is not a fixed structure.
The inventor has found that instant-fit plugs may perform less effectively than might have been expected. Problems seem to be linked to a variety of causes. The tricky shapes of the ear canals, e.g. with twists or a more or less pronounced oval shape, make them inherently difficult to seal off by a circular plug shape. A radially protruding skirt on a plug may, when compressed by the ear canal walls, tend to form irregular pleats or folds, bound to establish air leaks, and may, on withdrawal, tend to fold over backwards, causing discomfort during the withdrawal and compelling the user to straighten the skirt before renewed insertion.
Uncontrolled leaks are bound to cause problems e.g. with feedback, loss of sound power, poor mixing of amplified sound with direct sound etc.
Furnishing a skirt with slits or dividing it up into radial ribs may make it able to cope with a wide range of ear canal sizes, however, slits or spaces between ribs are bound to leave open spaces voiding the acoustic seal. Further, folds, ribs and edges may not be preferred due to risk of creating sensations of itching or tickling. These sensations can be annoying, keeping in mind that the wall of the ear canal moves with the jawbone, thus working on any object inserted in the ear canal.
The S-shape of the ear canal may cause the tip of an ear piece to end up in a slanted orientation where a sound output opening may be obscured or where a protruding flange seal does not seal properly against the ear canal wall. An ear piece with a protruding flange may end up in the ear canal in a state where part of the flange folds, leaving bypass openings.
The invention, in a first aspect, provides an ear piece as recited in claim 1.
Making the shroud oval permits a better adaptation to the ear canal, as ear canals of humans are generally oval. Further, the rotational capability permits the oval shroud to twist on the adapter during insertion of the ear plug into the ear canal for superior adaptation to different attitudes of the major axis of the oval cross-section of the human ear canal. This is important as human ears have been found to exhibit wide variation in the orientation of the major axis, and even a twisting orientation depending in the extent of entry into the ear canal. Making the stem and the shroud of the ear piece from different materials permit combining a sturdy core for a good grip on the speaker with a soft shroud for superior comfort.
In embodiments, the shroud is elliptic as seen in a direction along the sound conduit axis with a major axis at least 1.1 times, and preferably not longer than 1.7 times the length of the minor axis. By the soft resilient material, the bulb has a wide capacity of adapting to various shapes of ear canals. It is estimated that human ears exhibit degrees of eccentricity often ranging about 170%, i.e. the major axis is about 1.7 times the length of the minor axis. However, it is estimated that a bulb with a degree of eccentricity of 170% will be able to adapt to even rather extreme shapes of ear canals.
According to an embodiment, the adapter and the sound feeder means comprises a spout and socket combination for mating and rotatable attachment. This is a convenient design in manufacturing and performance
According to an embodiment, the stem and the shroud are made from resilient materials, where the material of the shroud is softer than the material of the stem. This enables the stem to maintain a secure grip on the spout, and enables providing a shroud with superior comfort.
According to an embodiment, the shroud comprises a generally round first end zone with a smooth outer surface, a general round second end zone with a smooth outer surface opposite the medial surface zone, and a mid zone intermediate the first end zone and the second end zone, wherein the mid zone is adapted by appropriate structural design for being softer to compression by the contact with ear canal wall than is the case with the first end zone and the second end zone.
Within the body of the present disclosure, the terms medial and lateral refer to the orientation of the ear tip when inserted into the human ear, i.e. medial is the direction towards the median plane of the head, viz. towards the tympanic membrane, while lateral is the direction away from the median plane of the head. The softer properties of the ear tip mid zone can be achieved by appropriate structural design, such as tapering wall thicknesses, arranging pleats or bellows shapes or by selecting materials with suitable softness.
Making the mid zone softer in compression means the ear tip is very soft in the pressure exerted on the ear canal wall and therefore comfortable for the user during insertion and during regular wear. The medial zone and the lateral zone (jointly referred to as the end zones) are less soft to compression than is the case with the mid zone. However, as the bulb is generally ball-shaped, the end zones will have a smaller diameter and therefore not in need of being compressed as much as is the case with the mid zone, and therefore not likely to exert any uncomfortable pressure on the ear canal. The somewhat more sturdy structures of the end zones make the ear tip easy in insertion, an observation borne out by a panel of test persons who reported a sensation of the ear tip tending to comfortably navigating its way through the twists and bends of the ear canal. Test persons further report that the novel ear tip achieves a firm seat in the ear canal with no propensity to dislodge during wear.
The bulb may seal against the ear canal wall at the medial zone, the mid zone, the lateral zone, or any combination thereof.
An embodiment provides the mid zone with pleats extending generally parallel to the axis. This endows the bulb with the capability of accepting substantial compression of the mid zone.
Making the pleats deepest at the mid zone and then tapering off towards both end zones calibrates the resilience to compression in order that it will not exhibit any abrupt changes.
Providing webs across the valleys in the pleats seals off the valleys against axial passage of air for optimal acoustic insulation.
In an embodiment, the bulb comprises a circumferential low ridge at the mid zone for sealing against the ear canal wall. This establishes a circumferential sealing zone, which supplements the sealing effect by the end zones. Having three circumferential sealing zones is important as the human ear canal normally exhibits bends, causing some of the sealing areas to be oriented obliquely to the ear piece axis, and therefore prone to introduce leakages against the canal wall.
In an embodiment, the bulb is reinforced around the lateral opening. The reinforcement, which may be implemented by bulking up the wall thickness, by adding struts, or by other structural means, makes the lateral zone less pliable in compression. This ensures that the lateral zone has suitable resilience, even if this part has an opening, i.e. it is not anchored to, or buttressed by, any core structure, for being free to expand axially, and for leaving a passage for air. The reinforcement also prevents the shroud from bending over backwards on withdrawal of the ear tip from the ear canal.
Further advantageous features appear from the claims.
Still other objects of the present invention will become apparent to those skilled in the art from the following description wherein the invention will be explained in greater detail.
By way of example, there is shown and described embodiments of this invention. As will be realized, the invention is capable of other different embodiments, and its several details are capable of modification in various, obvious aspects all without departing from the invention. Accordingly, the drawings and descriptions will be regarded as illustrative in nature and not as restrictive. In the drawings:
Reference is first made to
Ear canals come in many sizes and shapes. It is standard practice to supply instant-fit ear piece in a selection of sizes. Fits may end up differently; however, and the inventors have found that problems are widespread.
Reference is made to
Reference is next made to
Reference is made to
Reference is then made to
Reference is now made to
The sound output opening 11 is bridged by lug 12, which opens to opposing sides and spaces the bridge side openings from the ear canal wall. The vents 13 open up to the bulb inside and from there through lower opening 30 to the surroundings. The vents are spaced from the bridge side openings to avoid any risk of a wax build-up growing to establishing a common blockade of the openings, which might create an acoustic short-circuit.
For the ear tip, axis 19 generally constitutes an axis of rotational symmetry.
The section in
The material used for the ear tip is a softly resilient silicone rubber with a hardness in the range 10-90 Shore A, e.g. in the range 30-50 Shore A.
In a variation of this embodiment the bulb stem portion comprises a silicone rubber material with a hardness in the range 70-90 Shore A, while the bulb shroud portion comprises a silicone rubber material with a hardness in the range 10-40 Shore A.
The generally spherical ear tip comprises various zones that are perhaps easiest designated using the nomenclature pertaining to the Earth globe. Within this nomenclature the North Pole is regarded to point upwards, not to be confused with the orientation of the bulb of the ear tip, where the corresponding point is at the lug, which points medially, in the direction of the tympanic membrane, on inserting the ear tip into the canal.
The lug 12 (really the medial point) marks the North Pole. Next comes the northern tempered zone 24, the tropic zone 26, and the southern tempered zone 28, while the part further south is open. The northern tempered zone is demarcated from the tropic zone by bulb upper parallel (Tropic of Cancer) 25. The southern tempered zone is demarcated from the tropic zone by the bulb lower parallel (Tropic of Capricorn) 29.
On the outside, the shroud is smooth and spherical in the northern tempered zone and in the southern tempered zone, whereas it is has pleats in the tropical zone. The pleats run parallel to the axis and reach their maximum depth at the equator, then tapering away north and south to vanish at the upper and lower parallels. The shroud is softest at the tropical zone, where the pleats permit it to yield softly, peripherally and radially, to external axial pressure. The shroud is unrestrained at the southern end, a structure which permits it to also expand axially under external pressure.
The northern tempered zone is resilient, though buttressed by the core fixture 15 at the north polar zone. At the southern parallel, the shroud is reinforced by the wall structure by a bead 20 on the inside. The reinforcement helps preserving the ball-shape, and prevents the shroud from folding over backwards by the friction against the ear canal wall during an operation of withdrawing the ear tip.
Reference is now made to
Reference is next made to
The shroud preferably is made from silicone rubber 20-50 Shore A, and preferably 30 Shore A, which has been found to be soft and pliable for good user comfort. The stem is made from silicone rubber 60-90 Shore A, preferably 80 Shore A, which has been found to provide the stem with a secure retention to the spout.
As in the first embodiment, the shroud generally comprises lug 12, sound output openings 11, vents 13, upper zone 39 (i.e. the region adjacent the ear tip, which leads when the ear piece is pressed into the ear canal), mid zone 40 and lower zone 41. The pleated mid zone is softer to radial compression than both end zones, the upper end zone being buttressed by the structure around lug 12 and the lower end zone being supported by virtue of having a reduced radius comparing to the mid zone and by a slightly bulked up wall thickness around lower opening 30.
Reference is next made to
Reference is now made to
The third embodiment differs from the first and the second embodiment by the shroud not having pleats. This design is favored for ear pieces of very small sizes, where it would be difficult to mold the pleats. Suitable softness of the mid zone can be obtained by appropriate selection of materials and a careful design of the wall thickness.
The shroud and the stem are preferably is made of materials similar to those mentioned for the equivalent parts of the second embodiment.
As in the first embodiment, the shroud generally comprises lug 12, sound output openings 11, vents 13, upper zone 52 (i.e. the region adjacent the ear tip, which leads when the ear piece is pressed into the ear canal), mid zone 53 and lower zone 54. By its larger diameter, the mid zone is softer to radial compression than both end zones, the upper end zone being buttressed by the structure around lug 12 and the lower end zone being supported by virtue of a reduced radius comparing to that of the mid zone and by a slightly bulked up wall thickness around lower opening 57.
Reference is next made to
Further variations of the embodiments with other degrees of eccentricity can be used. Ovalities of ear canals have been found to range with a major axis about 170% of the minor axis.
Ear canals can be estimated to range from 6-14 mm in diameter. The ear tip is estimated to cover a range of ear canal sizes down to a diameter of 60 or 80% of the rated full size diameter, depending on circumstances such as the particular shape of ear canal, personal sensitivity to pressure etc. Thus a selection of maybe 3 to 7 sizes, suitably staggered, will accommodate the users well.
In variations, the ear piece is deployed in association with a headset for a telephone, a communications device or a music player. Implementations of the variations will be obvious to those skilled in the art.
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