U.S. patent number RE38,351 [Application Number 09/489,441] was granted by the patent office on 2003-12-16 for high fidelity insert earphones and methods of making same.
This patent grant is currently assigned to Etymotic Research, Inc.. Invention is credited to Steven J. Iseberg, Donald L. Wilson.
United States Patent |
RE38,351 |
Iseberg , et al. |
December 16, 2003 |
**Please see images for:
( Certificate of Correction ) ** |
High fidelity insert earphones and methods of making same
Abstract
An insert earphone is provided in which a piece of foam material
is used to resiliently mount a receiver within a chamber portion of
a one-piece plastic housing member. The receiver has an output port
extending through a central aperture of the piece of foam material
and into one end of a passage defined by a tubular portion of the
housing member with a damper being disposed in the other end of the
passage. The tubular portion is inserted into an ear tip or other
coupling device and has an enlarged diameter end section to achieve
a locking action. Two such insert earphones may be coupled through
cables to a junction unit and filters are provided for enhancing
the drive of the earphones at high frequencies, the filters being
preferably mounted in the junction unit.
Inventors: |
Iseberg; Steven J. (Palatine,
IL), Wilson; Donald L. (Barrington, IL) |
Assignee: |
Etymotic Research, Inc. (Elk
Grove Village, IL)
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Family
ID: |
46253227 |
Appl.
No.: |
09/489,441 |
Filed: |
January 21, 2000 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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597940 |
Feb 7, 1996 |
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430698 |
Apr 27, 1995 |
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880244 |
May 8, 1992 |
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Reissue of: |
770647 |
Dec 19, 1996 |
05887070 |
Mar 23, 1999 |
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Current U.S.
Class: |
381/380; 181/130;
381/328 |
Current CPC
Class: |
H04R
1/1016 (20130101); H04R 1/1033 (20130101); H04R
1/1058 (20130101); H04R 5/033 (20130101) |
Current International
Class: |
H04R
1/10 (20060101); H04R 025/00 () |
Field of
Search: |
;381/309,322,324,327,328,325,370,380 ;181/129,130,131,135
;379/430 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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2155276 |
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Sep 1985 |
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GB |
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0043700 |
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Mar 1983 |
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JP |
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0238196 |
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Oct 1986 |
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JP |
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0290295 |
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Dec 1987 |
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JP |
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Other References
Knopf Im Ohr, pp. 34, 35, Audio Jul., 1993. .
Little Feat, p. 36, Audio Jul., 1993. .
pp. 135, 136, Audio Jul., 1993. .
M.C. Killion: "An `Acoustically Invisible` Hearing Aid", Hearing
Instruments, vol. 39, No. 10, 1988. .
M.C. Killion, T.W. Tillman, "Evaluation of High-Fidelity Hearing
Aids", Journal of Speech and Hearing Research, vol. 25, 15-25,
Mar., 1982. .
M.C. Killion and W.J. Murphy; "Smoothing the ITE Response: The
BF-1743 Damped Coupling Assembly" Apr., 1981..
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Primary Examiner: Le; Huyen
Attorney, Agent or Firm: McAndrews, Held & Malloy,
Ltd.
Parent Case Text
This is a continuation of application Ser. No. 08/597,940, filed
Feb. 7, 1996, now abandoned, which is a continuation of application
Ser. 08/430,698, filed Apr. 27, 1995, now abandoned, which is a
continuation of Ser. No. 07/880,244 filed May 8, 1992, now
abandoned.
Claims
What is claimed is:
1. An insert earphone comprising: a unitary housing having a hollow
body portion, the hollow body portion having an end wall and an
open end disposed opposite the end .[.wall.]. .Iadd.wall,
.Iaddend.and a hollow elongated tubular portion extending from the
end wall; an end cap; a cable including a plurality of electrical
conductors extending from an electrical audio signal source
external to the housing, the cable being secured with the end cap,
the end cap connected to cover the open end of the hollow body
portion; a receiver for transducing electrical energy received
along the plurality of electrical conductors to sound energy, the
receiver being supported within the hollow body portion of the
housing and having a sound outlet port extending partially into the
hollow elongated tubular portion of the housing in a closely
conforming manner; an insert formed from a resilient material, the
insert being disposed between the receiver and at least one
interior wall of the unitary housing to inhibit movement of the
receiver within the hollow body portion and assisting to provide an
acoustic seal between the hollow body portion and the elongated
tubular portion; a damper supported within the hollow elongated
tubular portion of the housing at a position opposite the sound
outlet port of the receiver, sound from the sound outlet port of
the receiver being conducted to the damper by the hollow elongated
tubular portion; a resilient sealing member disposed over the
hollow elongated tubular portion for sealing with an ear canal of a
wearer; .Iadd.and .Iaddend. the earphone extending into and
substantially acoustically sealing the ear canal of the wearer when
inserted, the damper and receiver response compensating for loss of
external ear resonance and coupling resonance that otherwise would
occur when the insert earphone is inserted into the ear canal of
the wearer to thereby assist in providing a high fidelity
response.
2. An insert earphone comprising: a unitary housing having a hollow
body portion, the hollow body portion having an end wall, at least
one interior wall, and an open end disposed opposite the end wall,
and a hollow elongated tubular portion extending from the end wall;
a receiver for transducing electrical energy received into sound
energy, the receiver having a sound outlet port extending from an
end thereof; an insert formed of resilient material, the insert
having a substantially central opening therein; and wherein, during
assembly, the outlet port of the receiver is placed in the opening
of the insert and the receiver and insert are inserted as a unit
into the open end of the hollow body portion until the outlet port
engages and extends partially into the hollow elongated tubular
portion such that a portion of the insert is compressed between the
end of the receiver and the end wall, and other portions of the
insert are compressed between the receiver and the at least one
interior wall, thereby mounting the receiver within the hollow body
portion and assisting to provide an acoustic seal between the
hollow body portion and the elongated tubular portion while
providing for transmission of sound energy from the sound outlet
port through the hollow elongated tubular portion into the ear
canal of a wearer.
3. A high-fidelity insert earphone comprising: a unitary housing
having a hollow body portion, the hollow body portion having an end
wall, and a hollow elongated tubular portion extending from the end
wall; a receiver for transducing electrical energy received into
sound energy, the receiver having a sound outlet port extending
from an end thereof, the sound outlet port having a first end and a
second end; and an insert formed from a resilient material, the
insert being disposed between the end of the receiver and the end
wall and flanking .[.on.]. .Iadd.only .Iaddend.the second end of
the sound outlet port, the first end of the sound outlet port
mating with, directly contacting a surface of, and extending into
the hollow elongated tubular portion.
4. The high fidelity insert earphone of claim 3 wherein the insert
mounts and inhibits movement of the receiver within the hollow body
portion of the unitary housing.
5. The high-fidelity insert earphone of claim 3 further comprising
a damper supported within the hollow elongated tubular portion of
the housing at a position opposite the sound outlet port of the
receiver, sound from the sound outlet port of the receiver being
conducted to the damper by the hollow elongated tubular
portion.
6. The high-fidelity insert earphone of claim 5 further comprising
a resilient sealing member disposed over the hollow elongated
tubular portion for sealing with an ear canal of a wearer.
7. The high fidelity insert earphone of claim 6 wherein the
earphone extends into and substantially acoustically seals the ear
canal of a wearer.
8. The high fidelity insert earphone of claim 7 wherein the
earphone emulates a human ear's natural diffuse field response to
sound energy received.
9. The high fidelity insert earphone of claim 6 wherein the
resilient sealing member has a plurality of outwardly projecting
flange portions of generally conical form and of progressively
increasing diameters.
10. The high fidelity insert earphone of claim 9 wherein the
earphone extends into and substantially acoustically seals the ear
canal of a wearer.
11. The high fidelity insert earphone of claim 10 wherein the
earphone emulates a human ear's natural diffuse field response to
sound energy received.
12. An insert earphone comprising: a receiver for transducing
electrical energy received into sound energy, the receiver having a
sound outlet port extending from an end thereof, the sound outlet
port having a first end and a second end, the receiver having a
radial dimension and at least one outer surface; an insert formed
from a resilient material, and having an uncompressed thickness;
and a unitary housing having a hollow body portion, the hollow body
portion having at least one inner surface, a radial dimension, and
an end wall, and a hollow elongated tubular portion extending from
the end wall, the radial dimension of at least a portion of hollow
body portion being less than the sum of the radial dimension of the
receiver and the uncompressed thickness of the insert, and upon
assembly, a first portion of the insert being disposed and
compressed between the end of the receiver and the end wall, second
and third portions of the insert being disposed and compressed
between the at least one outer surface of the receiver and the at
least one inner surface of the hollow body portion, the first end
of the sound outlet port directly contacting a surface of the
hollow elongated tubular portion and extending into the hollow
elongated tubular portion, and only the second end of the sound
outlet port being flanked by the insert, the insert thereby
mounting the receiver in the hollow body portion and assisting to
provide an acoustic seal between the hollow body portion and the
elongated tubular portion of the housing.
13. A method of assembling an insert earphone comprising a receiver
having a sound outlet port extending from an end thereof, a unitary
housing having a hollow body portion, the hollow body portion
having an end wall and an open end disposed opposite the end wall,
and a hollow elongated tubular portion, and a resilient insert
having a substantially central opening therein, the method
comprising the steps of: placing the sound outlet port of the
receiver through the opening of the resilient insert; inserting the
receiver, sound outlet port first, and the resilient insert as a
unit into the open end of the hollow body portion; moving the
inserted receiver toward the end wall such that first and second
portions of the resilient insert are folded back in a direction
toward the open end and compressed between the receiver and at
least one inner surface of the hollow body portion; and matings
engaging the sound outlet port of the receiver with the hollow
elongated tubular portion such that a third portion of the
resilient insert is compressed between the end of the receiver and
the end wall.
14. The method of claim 13 further comprising the step of
operatively coupling an electrical energy source to the
receiver.
15. The method of claim 14 wherein the insert earphone further
comprises an end cap, and further comprising the step of securing
the end cap to the open end of the hollow body portion..Iadd.
16. An insert earphone comprising: a housing having a hollow body
portion, the hollow body portion having an end wall and an open end
disposed opposite the end wall, and a hollow elongated tubular
portion extending from the end wall; an end cap; a cable including
a plurality of electrical conductors extending from an electrical
audio signal source external to the housing, the cable being
secured with the end cap, the end cap connected to cover the open
end of the hollow body portion; a receiver for transducing
electrical energy received along the plurality of electrical
conductors to sound energy, the receiver being supported within the
hollow body portion of the housing and having a sound outlet port
extending partially into the hollow elongated tubular portion of
the housing in a closely conforming manner; an insert formed from a
resilient material, the insert being disposed between the receiver
and at least one interior wall of the housing to inhibit movement
of the receiver within the hollow body portion and assisting to
provide an acoustic seal between the hollow body portion and the
elongated tubular portion; a damper supported within the hollow
elongated tubular portion of the housing at a position opposite the
sound outlet port of the receiver, sound from the sound outlet port
of the receiver being conducted to the damper by the hollow
elongated tubular portion; a resilient sealing member disposed over
the hollow elongated tubular portion for sealing with an ear canal
of a wearer; and the earphone extending into and substantially
acoustically sealing the ear canal of the wearer when inserted, the
damper and receiver response compensating for loss of external ear
resonance and coupling resonance that otherwise would occur when
the insert earphone is inserted into the ear canal of the wearer to
thereby assist in providing a high fidelity
response..Iaddend..Iadd.
17. An insert earphone comprising: a housing having a hollow body
portion, the hollow body portion having an end wall, at least one
interior wall, and an open end disposed opposite the end wall, and
a hollow elongated tubular portion extending from the end wall; a
receiver for transducing electrical energy received into sound
energy, the receiver having a sound outlet port extending from an
end thereof; an insert formed from a resilient material, the insert
having a substantially central opening therein; and wherein, during
assembly, the outlet port of the receiver is placed in the opening
of the insert and the receiver and insert are inserted as a unit
into the open end of the hollow body portion until the outlet port
engages and extends partially into the hollow elongated tubular
portion such that a portion of the insert is compressed between the
end of the receiver and the end wall, and other portions of the
insert are compressed between the receiver and the at least one
interior wall, thereby mounting the receiver within the hollow body
portion and assisting to provide an acoustic seal between the
hollow body portion and the elongated tubular portion while
providing for transmission of sound energy from the sound outlet
port through the hollow elongated tubular portion into the ear
canal of a wearer..Iaddend..Iadd.
18. A high-fidelity insert earphone comprising: a housing having a
hollow body portion, the hollow body portion having an end wall,
and a hollow elongated tubular portion extending from the end wall;
a receiver for transducing electrical energy received into sound
energy, the receiver having a sound outlet port extending from an
end thereof, the sound outlet port having a first end and a second
end; and an insert formed from a resilient material, the insert
being disposed between the end of the receiver and the end wall and
flanking only the second end of the sound outlet port, the first
end of the sound outlet port mating with, directly contacting a
surface of, and extending into the hollow elongated tubular
portion..Iaddend..Iadd.
19. The high fidelity insert earphone of claim 18 wherein the
insert mounts and inhibits movement of the receiver within the
hollow body portion of the housing..Iaddend..Iadd.
20. The high-fidelity insert earphone of claim 18 further
comprising a damper supported within the hollow elongated tubular
portion of the housing at a position opposite the sound outlet port
of the receiver, sound from the sound outlet port of the receiver
being conducted to the damper by the hollow elongated tubular
portion..Iaddend..Iadd.
21. The high-fidelity insert earphone of claim 20 further
comprising a resilient sealing member disposed over the hollow
elongated tubular portion for sealing with an ear canal of a
wearer..Iaddend..Iadd.
22. The high fidelity insert earphone of claim 21 wherein the
earphone extends into and substantially acoustically seals the ear
canal of a wearer..Iaddend..Iadd.
23. The high fidelity insert earphone of claim 22 wherein the
earphone emulates a human ear's natural diffuse field response to
sound energy received..Iaddend..Iadd.
24. The high fidelity insert earphone of claim 21 wherein the
resilient sealing member has a plurality of outwardly projecting
flange portions of generally conical form and of progressively
increasing diameters..Iaddend..Iadd.
25. The high fidelity insert earphone of claim 24 wherein the
earphone extends into and substantially acoustically seals the ear
canal of a wearer..Iaddend..Iadd.
26. The high fidelity insert earphone of claim 25 wherein the
earphone emulates a human ear's natural diffuse field response to
sound energy received..Iaddend..Iadd.
27. An insert earphone comprising: a receiver for transducing
electrical energy received into sound energy, the receiver having a
sound outlet port extending from an end thereof, the sound outlet
port having a first end and a second end, the receiver having a
radial dimension and at least one outer surface; an insert formed
from a resilient material and having an uncompressed thickness; and
a housing having a hollow body portion, the hollow body portion
having at least one inner surface, a radial dimension, and an end
wall, and a hollow elongated tubular portion extending from the end
wall, the radial dimension of at least a portion of hollow body
portion being less than the sum of the radial dimension of the
receiver and the uncompressed thickness of the insert, and upon
assembly, a first portion of the insert being disposed and
compressed between the end of the receiver and the end wall, second
and third portions of the insert being disposed and compressed
between the at least one outer surface of the receiver and the at
least one inner surface of the hollow body portion, the first end
of the sound outlet port directly contacting a surface of the
hollow elongated tubular portion and extending into the hollow
elongated tubular portion, and only the second end of the sound
outlet port being flanked by the insert, the insert thereby
mounting the receiver in the hollow body portion and assisting to
provide an acoustic seal between the hollow body portion and the
elongated tubular portion of the housing..Iaddend..Iadd.
28. A method of assembling an insert earphone comprising a receiver
having a sound outlet port extending from an end thereof, a housing
having a hollow body portion, the hollow body portion having an end
wall and an open end disposed opposite the end wall, and a hollow
elongated tubular portion, and a resilient insert having a
substantially central opening therein, the method comprising the
steps of: placing the sound outlet port of the receiver through the
opening of the resilient insert; inserting the receiver, sound
outlet port first, and the resilient insert as a unit into the open
end of the hollow body portion; moving the inserted receiver toward
the end wall such that first and second portions of the resilient
insert are folded back in a direction toward the open end and
compressed between the receiver and at least one inner surface of
the hollow body portion; and matingly engaging the sound outlet
port of the receiver with the hollow elongated tubular portion such
that a third portion of the resilient insert is compressed between
the end of the receiver and the end wall..Iaddend..Iadd.
29. The method of claim 28 further comprising the step of
operatively coupling an electrical energy source to the
receiver..Iaddend..Iadd.
30. The method of claim 29 wherein the insert earphone further
comprises an end cap, and further comprising the step of securing
the end cap to the open end of the hollow body
portion..Iaddend..Iadd.
31. An insert earphone comprising: a housing having a hollow body
portion, the hollow body portion having an end wall and a hollow
elongated tubular portion extending from the end wall; a cable
including a plurality of electrical conductors extending from an
electrical audio signal source external to the housing; a receiver
electrically coupled to the plurality of electrical conductors, the
receiver for transducing electrical energy received along the
plurality of electrical conductors to sound energy, the receiver
being supported within the hollow body portion of the housing and
having a sound outlet port extending partially into the hollow
elongated tubular portion of the housing in a closely conforming
manner; an insert formed from a resilient material, the insert
being disposed between the receiver and at least one interior wall
of the housing to inhibit movement of the receiver within the
hollow body portion and assisting to provide an acoustic seal
between the hollow body portion and the elongated tubular portion;
a damper supported within the hollow elongated tubular portion of
the housing at a position opposite the sound outlet port of the
receiver, sound from the sound outlet port of the receiver being
conducted to the damper by the hollow elongated tubular portion; a
resilient scaling member disposed over the hollow elongated tubular
portion for sealing with an ear canal of a wearer; and the housing
extending into and substantially acoustically sealing the ear canal
of the wearer when inserted such that the housing is supported by
the ear of the wearer, the damper and receiver response
compensating for loss of external ear resonance and coupling
resonance that otherwise would occur when the insert earphone is
inserted into the ear canal of the wearer to thereby assist in
providing a high fidelity response without requiring a long
flexible tube between the hollow elongated tubular portion of the
housing and the resilient sealing member..Iaddend..Iadd.
32. The insert earphone of claim 31 wherein the sound outlet
portion extending partially into the hollow elongated tubular
portion directly contacts a surface of the hollow elongated tubular
portion..Iaddend..Iadd.
33. The high fidelity insert earphone of claim 31 wherein the
resilient sealing member has a plurality of outwardly projecting
flange portions of generally conical form and of progressively
increasing diameters..Iaddend..Iadd.
34. An insert earphone comprising: a housing having a hollow body
portion, the hollow body portion having an end wall and a hollow
elongated tubular portion extending from the end wall; a cable
including a plurality of electrical conductors extending from an
electrical audio signal source external to the housing; a receiver
electrically coupled to the plurality of electrical conductors, the
receiver for transducing electrical energy received along the
plurality of electrical conductors to sound energy, the receiver
being supported within the hollow body portion of the housing and
having a sound outlet port extending partially into the hollow
elongated tubular portion of the housing in a closely conforming
manner; an insert formed from a resilient material, the insert
being disposed between the receiver and at least one interior wall
of the housing; a damper supported within the hollow elongated
tubular portion of the housing at a position opposite the sound
outlet port of the receiver, sound from the sound outlet port of
the receiver being conducted to the damper by the hollow elongated
tubular portion; a resilient sealing member disposed over the
hollow elongated tubular portion for sealing with an ear canal of a
wearer; and the housing extending into and substantially
acoustically sealing the ear canal of the wearer when inserted such
that the housing is supported by the ear of the wearer, the damper
and receiver response compensating for loss of external ear
resonance and coupling resonance that otherwise would occur when
the insert earphone is inserted into the ear canal of the wearer to
thereby assist in providing a high fidelity response without
requiring a long flexible tube between the hollow elongated tubular
portion of the housing and the resilient sealing
member..Iaddend..Iadd.
35. The insert earphone of claim 34 wherein the sound outlet port
extending partially into the hollow elongated tubular portion
directly contacts a surface of the hollow elongated tubular
portion..Iaddend..Iadd.
36. The high fidelity insert earphone of claim 34 wherein the
resilient sealing member has a plurality of outwardly projecting
flange portions of generally conical form and of progressively
increasing diameters..Iaddend..Iadd.
37. The insert earphone of claim 34 wherein the insert inhibits
movement of the receiver within the hollow body
portion..Iaddend..Iadd.
38. The insert earphone of claim 34 wherein the insert assists in
providing an acoustical seal between the hollow body portion and
the elongated tubular portion..Iaddend..Iadd.
39. An insert earphone comprising: a housing having a hollow body
portion, the hollow body portion having an end wall and a hollow
elongated tubular portion extending from the end wall; a filter
electrically coupled to an electrical audio signal source external
to the housing, the filter for receiving electrical signals from
the audio signal source and for modifying frequency components of
the electrical signals received; a receiver electrically coupled to
an output of the filter, the receiver for transducing electrical
received from the filter to sound energy, the receiver being
supported within the hollow body portion of the housing and having
a sound outlet port extending partially into the hollow elongated
tubular portion of the housing in a closely conforming manner; an
insert formed from a resilient material, the insert being disposed
between the receiver and at least one interior wall of the housing;
a damper supported within the hollow elongated tubular portion of
the housing at a position opposite the sound outlet port of the
receiver, sound from the sound outlet port of the receiver being
conducted to the damper by the hollow elongated tubular portion; a
resilient sealing member disposed over the hollow elongated tubular
portion for sealing with an ear canal of a wearer; and the housing
extending into and substantially acoustically sealing the ear canal
of the wearer when inserted such that the housing is supported by
the ear of the wearer, the damper and receiver response
compensating for loss of external ear resonance and coupling
resonance that otherwise would occur when the insert earphone is
inserted into the ear canal of the wearer to thereby assist in
providing a high fidelity response without requiring a long
flexible tube between the hollow elongated tubular portion of the
housing and the resilient sealing member..Iaddend..Iadd.
40. The insert earphone of claim 39 wherein the sound outlet port
extending partially into the hollow elongated tubular portion
directly contacts a surface of the hollow elongated tubular
portion..Iaddend..Iadd.
41. The insert earphone of claim 39 wherein the earphone emulates a
human ear's natural diffuse field response to sound energy
received..Iaddend..Iadd.
42. The high fidelity insert earphone of claim 39 wherein the
resilient sealing member has a plurality of outwardly projecting
flange portions of generally conical form and of progressively
increasing diameters..Iaddend..Iadd.
43. The insert earphone of claim 39 wherein the insert inhibits
movement of the receiver within the hollow body
portion..Iaddend..Iadd.
44. The insert earphone of claim 39 wherein the insert assists in
providing an acoustical seal between the hollow body portion and
the elongated tubular portion..Iaddend..Iadd.
45. The insert earphone of claim 39 wherein modifying frequency
components of the electrical signals received comprises increasing
high frequency components of the electrical signals
received..Iaddend..Iadd.
46. The insert earphone of claim 39 wherein the filter is located
in a junction unit external to the housing..Iaddend..Iadd.
47. The insert earphone of claim 39 wherein the filter is located
in the housing..Iaddend..Iadd.
48. An insert earphone comprising: a housing having a hollow body
portion, the hollow body portion having an end wall and a hollow
elongated tubular portion extending from the end wall; a cable
including a plurality of electrical conductors extending from an
electrical audio signal source external to the housing; a receiver
electrically coupled to the plurality of electrical conductors, the
receiver for transducing electrical energy received along the
plurality of electrical conductors to sound energy, the receiver
being supported within the hollow body portion of the housing and
having a sound outlet port extending partially into the hollow
elongated tubular portion of the housing in a closely conforming
manner; an insert formed from a resilient material, the insert
being disposed between the receiver and at least one interior wall
of the housing; a damper; a resilient sealing member disposed over
the hollow elongated tubular portion for sealing with an ear canal
of a wearer; and the housing extending into and substantially
acoustically sealing the ear canal of the wearer when inserted such
that the housing is supported by the ear of the wearer, the damper
and receiver response compensating for loss of external ear
resonance and coupling resonance that otherwise would occur when
the insert earphone is inserted into the ear canal of the wearer to
thereby assist in providing a high fidelity response without
requiring a long flexible tube between the hollow elongated tubular
portion of the housing and the resilient sealing
member..Iaddend..Iadd.
49. The insert earphone of claim 48 wherein the sound outlet port
extending partially into the hollow elongated tubular portion
directly contacts a surface of the hollow elongated tubular
portion..Iaddend..Iadd.
50. The insert earphone of claim 48 wherein the earphone emulates a
human ear's natural diffuse field response to sound energy
received..Iaddend..Iadd.
51. The high fidelity insert earphone of claim 48 wherein the
resilient sealing member has a plurality of outwardly projecting
flange portions of generally conical form and of progressively
increasing diameters..Iaddend..Iadd.
52. The insert earphone of claim 48 wherein the insert inhibits
movement of the receiver within the hollow body
portion..Iaddend..Iadd.
53. The insert earphone of claim 48 wherein the insert assists in
providing an acoustical seal between the hollow body portion and
the elongated tubular portion..Iaddend..Iadd.
54. The insert earphone of claim 48 wherein the damper comprises an
acoustic damper..Iaddend..Iadd.
55. The insert earphone of claim 48 wherein the damper is supported
within the hollow elongated tubular portion of the
housing..Iaddend..Iadd.
56. The insert earphone of claim 55 wherein the damper is
positioned opposite the sound outlet port of the receiver..Iaddend.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to earphones and methods of making the same
to obtain earphones and earphone assemblies which reproduce sounds
with very high fidelity and with minimum noise and which are
suitable for use by the most discriminating listeners. The
earphones and assemblies of the invention are very compact and
light in weight, are highly reliable and are readily and
economically manufacturable.
2. Background of the Prior Art
"Audiophile" earphones have been marketed for use by audiophiles or
discriminating listeners interested in the highest possible sound
reproduction. Such audiophile earphones have been ostensibly
capable of effecting high fidelity sound reproduction although it
has been recognized by many users as well as the makers of such
earphones that they have left much to be desired with respect to
fidelity of reproduction. It has apparently been assumed by such
users and makers that deficiencies in quality of sound reproduction
are an unavoidable result of the use of earphones.
In a separate audiometry art, earphones have also been developed
and marketed in limited quantities for use in specialized
audiometry applications to measure the responses of a patient's ear
and having features for obtaining desired response characteristics,
one disclosure being contained in the Killion U.S. Pat. No.
4,763,753, issued Aug. 16, 1988. Another separate art, the hearing
aid art, also contains many disclosures related to the achievement
of improved response characteristics, including a paper entitled
"SMOOTHING THE ITE RESPONSE: THE BF-1743 DAMPED COUPLING ASSEMBLY"
by Mead C. Killion and William J. Murphy, first published in April
1981 and revised June 1982, by Industrial Research Products, Inc.
Elk Grove Village, Ill. Such disclosures in the audiometry and
hearing aid art relate to devices of relatively expensive
construction which are designed for specialized applications and
marketed in limited quantities. The applicability of the audiometry
and hearing aid arts to the making of earphones for use in high
fidelity sound reproduction has apparently gone unrecognized.
SUMMARY OF THE INVENTION
This invention was evolved after learning of the deficiencies of
earphones marketed for use by audiophiles and with the general
object of providing earphones which have improved high fidelity
response characteristics and which are readily and economically
manufacturable.
Important aspects of the invention relate to the recognition and
discovery of problems with prior art arrangements and their causes
and to an analysis of what is necessary to overcome such problems
and otherwise provide improved earphones. It was discovered that
one serious problem with audiophile earphones has been related to
the failure to recognize the need to compensate for loss of
external-ear resonance when using an earphone and the failure to
provide compensating acoustic characteristics between the ear canal
of a user and the transducer or receiver used to develop an audio
signal from an applied electrical signal. It was further discovered
that features of a damped coupling assembly of the hearing aid
disclosed in the aforementioned Killion and Murphy paper might be
applied with advantage to the construction of an audiophile
earphone. With a damped coupling assembly as disclosed in that
paper, a damper is coupled through a tube to an output port of a
receiver and is disposed within the tip of an earmold. The
arrangement produces a frequency response which will compensate for
the loss of external ear resonance and which is largely independent
of the total length of the coupling between the receiver and the
earmold tip.
In accordance with the invention, an audiophile insert earphone is
provided which uses a damped coupling assembly similar to that
disclosed in the above-mentioned Killion and Murphy paper and
operative to provide compensation for the loss of external-ear
resonance. In accordance with one important feature of the
invention, a pair of such earphones are combined in a dual earphone
assembly usable for stereophonic reproduction.
Additional important features of the invention relate to features
of construction which facilitate manufacture of insert earphones
and which at the same time achieve reproduction of sounds with very
high fidelity and with a high degree of reliability. Certain of
such features relate to the provision of a housing member which can
be readily molded from plastic in one piece and which serves the
functions of connecting to an outlet port of a receiver, supporting
a damper and providing a sound passage. The housing member also
serves to releasably connect to a coupling device such as an
earmold or ear tip and it performs all of such functions with a
high degree of accuracy and reliability. Others such features
relate to the provision of a resilient support for the receiver to
minimize the effects of vibrations and noise and to methods of
making the earphone to facilitate manufacture at low cost.
Another feature relates to the combination of electrical filters
with the earphone and its damped coupling assembly to achieve
optimum overall results.
Still another feature relates to a construction to facilitate
removal and replacement of a damper and to the provision of a tool
for that purpose.
This invention contemplates other objects, features and advantages
which will become more fully apparent from the following detailed
description taken in conjunction with the accompanying
drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates a high fidelity insert earphone assembly of the
invention;
FIG. 2 is a cross-sectional view of one earphone of the assembly of
FIG. 1, taken substantially along line 2--2 of FIG. 1;
FIG. 3 shows a piece of resilient material used in construction of
the earphone of FIG. 1;
FIG. 4 is a cross-sectional view taken substantially along line
4--4 of FIG. 2;
FIG. 5 is a circuit diagram of a electrical filter unit of the
assembly of FIG. 1; and
FIG. 6 is a side elevational view, partly in section, illustrating
a device usable for removal of dampers of the earphones of the
invention.
DESCRIPTION OF A PREFERRED EMBODIMENT
In FIG. 1, reference numeral 10 generally designates an earphone
assembly which is constructed in accordance with the principles of
this invention and which is suitable for use by an audiophile, for
example. It will be understood, however, that a number of features
of the invention are not limited to any particular use. Certain
features may be used, for example, in the construction of hearing
aids for use by persons having a hearing impairment.
The illustrated assembly 10 includes a pair of earphones 11 and 12
for insertion into the entrances of the ear canals of a user. A
pair of cables 13 and 14 connect earphones 11 and 12 to a junction
unit 15 and a common cable 16 connects the junction unit 15 to a
plug connector 17 which may be connected to an output jack of a
stereophonic amplifier, for example.
FIG. 2 is a cross-sectional view of the earphone 11, the
construction of the other earphone 12 being preferably identical to
that of the earphone 11. The earphone 11 comprises a receiver 18
which is mounted in a chamber portion 19 of a housing member 20.
The receiver 18 has an acoustic output port and has electrical
input terminals 23 and 24 and is operative for generating an
acoustic output signal at the output port 22 as a function of an
electrical signal applied to the terminals 23 and 24. The terminals
23 and 24 are connected through wires 25 and 26 to conductors of
the cable 13 and an outer sheath 27 of the cable 13 is bonded to a
strain relief member 28. Member 28 is secured in an opening of an
end cap 29 which is secured to one end of the housing member 20 to
close one end of the chamber portion 19.
The housing member 20 includes a wall 32 at an opposite end of the
chamber portion 19 and an outer wall 34 of the chamber portion 19
which is in surrounding relation to the receiver 18 and which may
preferably be of generally cylindrical form.
The housing member 20 further includes a tubular portion 35 which
projects from the end wall 32 of the chamber portion of the housing
member and which is inserted in an opening 37 of an acoustic
coupling device 38 arranged to be inserted into the entrance of an
ear canal of a user. As shown, the coupling device 38 is in the
form of an eartip of a soft compliant material and has three
outwardly projecting flange portions 39, 40 and 41 which are of
generally conical form and of progressively increasing diameters,
arranged to conform to the inner surface portions of the entrance
of the ear canal of the user and to provide a seal limiting
transmission of sound to the ear canal.
In accordance with a releasable lock feature of the invention, an
end section 42 of the tubular portion 35 is of increased
cross-sectional size to provide an external shoulder 43 in facing
relation to the wall 32. In assembly, a portion 44 of the compliant
material of the device 38 is stretched over the end section 42 and
then expands into the space between the shoulder 43 and the wall 32
as shown, so as to lock the device 38 and housing member 20
together while permitting disassembly when desired.
Custom earmolds or other types of coupling devices may be
substituted for the illustrated device 38, the subassembly of the
housing member 20, receiver 18 and other parts being thus usable
with various types of coupling devices.
In accordance with further important features of the invention, the
tubular portion 35 defines a passage 46 which has an outlet end
portion 47 for propagation of acoustic energy into the earcanal of
a user and an inlet end portion 48 in communication with the outlet
port .[.20.]. .Iadd.22 .Iaddend.of the receiver 18. The outlet port
22 is preferably in the form of a tubular member which is fitted
into the inlet end portion 47 of the passage 46 as shown. An
acoustic damper 50 is fitted in the outlet end portion 47 of the
passage 46 and, as illustrated, includes a cup-shaped screen member
51 secured in a cylindrical support member 52. The outlet end
portion 47 preferably has an enlarged diameter to provide a
shoulder 53 operative to limit movement of the damper 50 toward the
receiver 18 during assembly and to accurately fix its position. As
shown, the portion of the screen member 51 which is transverse to
the direction of sound transmission is in recessed relation to the
end of the tubular housing portion .[.22.]. .Iadd.35 .Iaddend.and
the terminal end of the tubular housing portion is spaced a
substantial distance from the terminal end of the coupling device,
the result being that problems with wax accumulations on the screen
are minimized. However, should such accumulations occur, a special
removal tool as hereinafter described may be used to remove a
clogged damper 50 which can then be replaced with a new damper.
With the construction as thus far described, the housing member 20
can be readily molded from plastic in one piece and it serves the
functions of connecting to the outlet port of the receiver,
supporting the damper, providing a sound passage and releasably
connecting to a coupling device which may be of various possible
types, such functions being performed with a high degree of
accuracy and reliability.
Additional important features relate to the provision of a
resilient support for the receiver 18 to minimize problems with
noise and vibrations while facilitating assembly of the earphone. A
piece of foam material 54 is provided having a generally
rectangular form and a central opening 55 as depicted in FIG. 3. In
assembly, strain relief member 28 at the end of the cable 13 is
installed in an opening in the end cap 29 and the conductors of the
cable are connected directly or through the separate wires 25 and
26 as illustrated to the terminals 23 and 24 of the receiver 18,
being optionally extended through a resilient foam element 56, as
shown. Then the output port 22 of the receiver is inserted in the
opening 55 of the piece 54 and the receiver is inserted into the
chamber portion 19 and moved toward the wall 32 to press fit the
output port 22 into the inlet end portion 48 of the passage 46.
During this assembly step, a portion 58 of the piece 54 is
compressed between the end of the receiver 18 and the wall 32 and
portions 59 and 60 of the piece 54 are folded back and compressed
between the receiver and the outer wall 34 of the chamber portion
19. As shown in the cross-sectional view of FIG. 4, parts of the
folded-back portions 59 and 60 extend along the sides of the
receiver 18 as well as along the top and bottom of the receiver 18.
This assembly step is readily and quickly performed and results in
a resilient support of the receiver 18 within the housing member 20
in a manner such as to minimize transmission of noise and
vibrations thereto, functioning with a high degree of reliability.
It also results in an acoustic seal between the output port 22 and
the inlet end 48 of passage 46. As a final assembly step, an epoxy
or equivalent bonding means is used to secure the end cap 29 to the
end of the housing member 20.
FIG. 5 is a schematic diagram of the configuration of the junction
unit 15 which connects the earphone cables 13 and 14 to the common
cable 16 and which includes special electrical filters for
enhancing the performance of the earphones 11 and 13. One conductor
63 and one conductor 64 of the cables 13 and 14 are directly
connected to a ground conductor 65 of the common cable 16. A second
conductor 67 of the cable 13, a second conductor 68 of the cable
14, and conductors 69 and 70 of cable 16 are respectively connected
to pads 71, 72, 73 and 74 of a circuit board 76 which is formed
with two circuits operative to increase the signal applied to the
receivers of the earphones 11 and 12 as a function of increasing
frequency.
As shown, a capacitor 77 and a resistor 78 are connected in series
between pads 71 and 73 while a resistor 80 is connected directly
between pads 71 and 73, in parallel with the series combination of
capacitor 77 and resistor 78. Similarly, a capacitor 81 and a
resistor 82 are connected in series between pads 72 and 74 while a
resistor 84 is connected directly between pads 71 and 73. It will
be apparent that at very low frequencies, when the capacitive
reactance is high, the series impedances are determined primarily
by the value of the resistors 80 and 84. As the frequency
increases, the series impedances are reduced, increasing the
amplitudes of higher frequency components of the applied
signals.
This electrical filtering operation is found to be highly
desirable, permitting the use of an amount of acoustic damping
sufficient to smooth out peaks in the acoustic responses of the
earphones 11 and 12 while obtaining optimum frequency response
characteristics. By way of example, the value of each of the
resistors 78, 80, 82 and 84 may be 100 ohms and the value of each
of the capacitors 77 and 81 may be 0.22 microfarads. The circuit
board 76 and the parts thereon preferably have quite small
dimensions. Each of the resistor and capacitor parts preferably has
maximum dimensions of 0.150".times.0.300".times.0.100". These
dimensions are desirable to obtain a compact junction unit and are
such that if desired, as when a single earphone is to be used, the
filter for each filter might be located within the earphone, e.g.
between the receiver 18 and the end cap 29. In a two earphone
assembly such as the illustrated assembly 10, however, it is
generally preferable to locate the filters in the junction unit
15.
FIG. 6 illustrates a tool usable for removal and replacement of a
damper which has become clogged with wax or otherwise defective. A
support rod 86 carries a threaded element 87 which has a pointed
end 88 to be pushed into the screen of a defective damper while the
rod 86 is rotated to engage the threads of the element 87 with a
lip of the cylindrical support 52 of the damper 50; the rod 86
being then retracted to withdraw the defective damper. Replacement
dampers 89 may be contained in a chamber 90 within the support rod
86 and may be accessed by removal of an extension 91 of the rod 86,
the extension 91 having a reduced diameter threaded end portion 92
which is screwed into an internally threaded end portion of the
replacement damper chamber 90.
.Iadd.Aspects of the present invention described above enable an
insert earphone that provides high fidelity sound reproduction,
without requiring a long flexible tube between a hollow elongated
tubular portion of the insert earphone housing and a resilient
sealing member that seals with the ear canal of a
wearer..Iaddend.
It will be understood that modifications and variations may be
effected without departing from the spirit and scope of the novel
concepts of this invention.Iadd...Iaddend.
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