 |
Claims  |
|
|
That which is claimed is:
1. A radiotelephone, comprising:
a radiotelephone housing defining a cavity with an upper portion therein,
said housing including an outer wall with at least one opening therein;
a microphone disposed in said housing cavity in alignment with said outer
wall opening;
a printed circuit board disposed within said housing cavity operably
associated with said microphone; and
an electrically conductive grommet having opposing first and second ends
and defining a longitudinal axis relative thereto, said grommet including
a longitudinally extending passage for holding said microphone therein,
wherein said grommet first end is configured to contact said printed
circuit board, and wherein said electrically conductive grommet
continuously extends between said printed circuit board and said upper
portion of said housing cavity.
2. A radiotelephone according to claim 1, wherein said printed circuit
board includes ground and signal contacts, and wherein said ground contact
is configured as a continuous circumferentially extending ground contact
surface, and wherein said grommet forms a continuous connection with said
ground contact surface.
3. A radiotelephone according to claim 1, further comprising a connector
positioned intermediate of said microphone and said printed circuit board,
and wherein said grommet is configured to receive said elastomer connector
and said microphone therein, and wherein said grommet is a unitary body.
4. A radiotelephone according to claim 3, wherein said connector is an
elastomer connector.
5. A radiotelephone according to claim 1, wherein said grommet is a
conductive elastomer grommet configured to acoustically isolate and
electrically shield said microphone.
6. A radiotelephone according to claim 5, wherein said conductive elastomer
grommet is a silver filled silicone grommet.
7. A radiotelephone according to claim 1, wherein said grommet second end
is substantially flush with said microphone.
8. A radiotelephone according to claim 1, wherein said grommet second end
contacts said housing adjacent said at least one opening therein.
9. A radiotelephone according to claim 8, said microphone having first and
second ends, wherein said second end is recessed a predetermined distance
into said grommet.
10. A radiotelephone according to claim 2, wherein said grommet first end
includes a circumferentially extending ridge.
11. A radiotelephone, comprising:
a radiotelephone housing defining a cavity therein, said housing including
an outer wall with at least one opening therein;
a microphone disposed in said housing cavity in alignment with said outer
wall opening;
a printed circuit board disposed within said housing cavity operably
associated with said microphone; and
an electrically conductive grommet having opposing first and second ends
and defining a longitudinal axis relative thereto, said grommet including
a longitudinally extending passage for holding said microphone therein,
wherein said grommet first end is configured to contact said printed
circuit board,
and wherein said grommet is a conductive elastomer grommet configured to
acoustically isolate and electrically shield said microphone, and wherein
said grommet includes at least one seal extending substantially
perpendicular to said longitudinal axis for acoustically dampening forces
transmitted about said microphone.
12. A radiotelephone, comprising:
a radiotelephone housing defining a cavity therein, said housing including
an outer wall with at least one opening therein;
a microphone disposed in said housing cavity in alignment with said outer
wall opening;
a printed circuit board disposed within said housing cavity operably
associated with said microphone; and
an electrically conductive grommet having opposing first and second ends
and defining a longitudinal axis relative thereto, said grommet including
a longitudinally extending passage for holding said microphone therein,
wherein said grommet first end is configured to contact said printed
circuit board, wherein said printed circuit board includes ground and
signal contacts, and wherein said grommet forms a continuous connection
with said ground contact, and wherein said housing includes an inner wall
opposite said outer wall and said inner wall includes a pair of
longitudinally extending opposing grommet walls and a planar portion
therebetween, and wherein said grommet firmly contacts each of said inner
walls, said planar portion, and said printed circuit board to define an RF
shield therebetween.
13. A radiotelephone microphone shield grommet, said grommet comprising:
a conductive flexible cylindrical body having an outside wall and opposing
first and second ends and defining a longitudinal passage therebetween,
wherein said grommet is configured to be operably associated with an
electrical ground contact, and wherein said grommet includes at least one
circumferential radially extending protrusion positioned on said outside
wall thereby providing acoustic dampening for said microphone.
14. A radiotelephone microphone shield grommet according to claim 13,
wherein said first end includes a circumferentially extending continuous
ridge therearound.
15. A radiotelephone microphone shield grommet according to claim 13,
wherein said passage is configured to receive a radiotelephone microphone
therein.
16. A radiotelephone microphone shield grommet according to claim 15,
wherein said passage is sized to contact and firmly hold the microphone
therein thereby acoustically isolating and electrically shielding the
microphone from undesired signal distortions.
17. A radiotelephone microphone shield grommet, said grommet comprising:
a conductive flexible cylindrical body having opposing first and second
ends and defining a longitudinal passage therebetween, wherein said
grommet is configured to be operably associated with an electrical ground
contact, wherein said passage is configured to receive a radiotelephone
microphone therein, and wherein said passage is sized to contact and
firmly hold the microphone therein thereby acoustically isolating and
electrically shielding the microphone from undesired signal distortions,
and wherein said passage includes first and second portions, said second
portion having a smaller diameter than said first portion, said second
portion is configured adjacent said first end of said grommet, and wherein
said first portion is sized to receive the microphone in abutting contact
therein, said second portion is sized and configured to enclose a
microphone connector therein.
18. A radiotelephone microphone shield assembly for acoustically isolating
and electrically shielding the microphone in a radiotelephone, comprising;
a radiotelephone housing having an aperture disposed therein;
a microphone having opposing first and second ends disposed in said housing
such that said first end is in communication with said aperture;
a printed circuit board disposed in said housing and operably associated
with said microphone;
an elastomer connector disposed between said microphone and said printed
circuit board to provide a signal path therebetween; and
a conductive grommet positioned in said housing intermediate of said
housing aperture and said printed circuit board, said grommet having
opposing first and second ends and a passage defined therebetween, said
passage configured to receive said microphone and said elastomer connector
therein, wherein said grommet is sized such that said first end contacts
said housing adjacent said aperture and said opposing second end extends
to firmly contact said printed circuit board, the assembly providing a
columnated shield along said microphone.
19. An assembly according to claim 18, wherein said columnated shield is
continuous about the length of said microphone.
20. An assembly according to claim 18, said microphone having first and
second opposing ends and a longitudinally extending body therebetween,
wherein said first end is free to communicate with said aperture, and said
second end includes a central signal portion in contact with said
elastomer connector, and wherein said longitudinally extending body is
fully enclosed within said grommet.
21. An assembly according to claim 20, wherein said grommet extends from
the printed circuit board to the top of said microphone, such that the
microphone first end is substantially flush with said grommet first end.
22. An assembly according to claim 20, wherein said grommet is a silver
filled silicon grommet.
23. A radiotelephone, comprising:
a radiotelephone housing defining a cavity therein;
a microphone disposed in said housing cavity;
a printed circuit board disposed within said housing cavity operably
associated with said microphone; and
a conductive grommet having opposing first and second ends defining a
longitudinal passage therebetween, said passage configured to receive said
microphone to provide a shield therefor.
24. A radiotelephone according to claim 23, wherein said printed circuit
board includes ground and signal contacts, and wherein said grommet forms
a continuous connection with at least one of said ground contacts.
25. A radiotelephone according to claim 23, said radiotelephone further
comprising an elastomer holder positioned intermediate of said microphone
and said printed circuit board, and wherein said grommet is configured to
receive said elastomer holder and said microphone therein.
26. A radiotelephone according to claim 23, wherein said grommet is a
conductive elastomer grommet configured to acoustically isolate and
electrically shield said microphone.
27. A radiotelephone according to claim 26, wherein said conductive
elastomer grommet is a silver filled silicone grommet.
28. A radiotelephone, comprising:
a radiotelephone housing defining a cavity therein;
a microphone disposed in said housing cavity;
a printed circuit board disposed within said housing cavity operably
associated with said microphone; and
a conductive elastomer grommet having opposing first and second ends
defining a longitudinal passage therebetween, said passage configured to
receive said microphone to acoustically isolate and electrically shield
said microphone, wherein said conductive elastomer grommet is a silver
filled silicone grommet, and wherein said grommet includes at least one
seal extending substantially perpendicular to said longitudinal passage
for acoustically dampening forces transmitted about said microphone. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
FIELD OF THE INVENTION
The present invention relates to radiotelephones, and more particularly
relates to shielding for microphones in radiotelephones.
BACKGROUND OF THE INVENTION
Generally stated, radiotelephones receive and transmit radio-frequency
("RF") radiotelephone signals via incoming and outgoing receive and
transmit signal paths. The receive and transmit signal paths typically
include components such as microphones and antennas operably associated
with a printed circuit board (for signal processing and other functions)
disposed in a radiotelephone housing.
Typically, the microphone is positioned in the radiotelephone such that
during use it is close to a user's mouth and free to receive the auditory
signals associated with a user's speech. Generally described, the
microphone receives the auditory signals corresponding to a user's speech
and then relays the received auditory signals to the printed circuit board
for further processing. The received signal is ultimately directed as an
output signal out of the radiotelephone to a remote site. The output
signal is typically transmitted out of the radiotelephone through a signal
path which includes the antenna.
Many of the more popular hand-held telephones are undergoing
miniaturization. Indeed, many of the contemporary models are only 10-12
centimeters in length. Because the printed circuit board is disposed
inside the radiotelephone, its size is also shrinking, corresponding to
the miniaturization of the portable radiotelephone. As the radiotelephone
reduces in size, it constrains the physical configuration or arrangement
of the internal components. For example, many integrated components such
as the antenna and microphone can be positioned in relatively close
proximity of each other. Unfortunately and undesirably, RF energy from the
antenna can find its way into the receiving signal path and distort the
sound as received in the microphone. Indeed, the distortion is generally
frequency dependent and produces an audible (and potentially irritating)
sound which is descriptively termed "motorboating".
Generally stated, microphones are difficult to adequately shield due to
design constraints such as acoustic isolation, short conductor leads for
low signal loss, and an aperture for sound transmission disposed adjacent
the aperture in the housing as described above. An electrical connection
is made between the microphone and the printed circuit board through
flexible means such as wires, elastomeric connectors, and springs. Some of
the connections, such as the elastomeric connector, can be sandwiched
between the microphone and the printed circuit board to dampen or absorb
shocks and help acoustically isolate and thus protect the integrity of the
signal at this connection.
In the past, some radiotelephones have metallized the housing front next to
the microphone or next to the perimeter of the rubber mounting connector,
these have had limited success in attempting to resolve the motorboating
condition. Further disadvantageous, metallizing components can be costly.
Additionally, capacitors have been used in an attempt to filter the signal
distortions due to RF interference. Unfortunately, these attempts have had
less than satisfactory results. This is especially true as the operating
frequencies of the radiotelephones increase. Indeed, many radiotelephones
can operate at frequencies at 800 Mhz and greater, even up to 1.9 GHz.
Unfortunately, the signal distortions can increase or become more
problematic as the operating frequency increases. Further, many
radiotelephones operate in dual band or full duplex; each of which can
potentially further exacerbate the problem. For example, the dual band
antenna's radiation pattern may produce additional RF energy directed at
the microphone.
OBJECTS AND SUMMARY OF THE INVENTION
It is therefore a first object of the present invention to reduce the
amount of spurious emission of RF energy introduced into the microphone or
acoustic circuit.
It is another object to provide a radiotelephone with a cost effective way
to reduce signal distortions attributed to RF signal interference in
received signals.
It is yet another object of the present invention to improve the signal
quality of the input signal and to reduce the level of "motorboating" in
high frequency dual-band radiotelephones.
These and other objects are satisfied by the present invention which
provides as a first aspect a signal shielding conductive grommet
configured to receive the microphone therein. In particular, the
radiotelephone includes a radiotelephone housing which defines a cavity
therein. The radiotelephone also includes a microphone disposed in the
housing cavity and a printed circuit board disposed within the housing
cavity. The printed circuit board is operably associated with the
microphone. The radiotelephone also includes a conductive grommet having
opposing first and second ends which define a longitudinal passage
therebetween. The passage is configured to receive the microphone to
provide a shield therefor.
In one embodiment, the housing includes an outer wall with at least one
opening formed therein. The radiotelephone also includes a microphone
disposed in the housing cavity in alignment with the outer wall opening. A
printed circuit board is also disposed within the housing cavity and is
operably associated with the microphone. The radiotelephone further
includes an electrically conductive grommet which holds the microphone
therein and contacts the printed circuit board.
Preferably, the printed circuit board includes ground and signal contacts
such that the grommet contacts and forms a continuous connection with at
least one of the circuit board ground contacts. Further preferably, the
grommet is a conductive elastomer grommet such as a silver filled silicone
which is configured to acoustically isolate and electrically shield the
microphone. The flexible grommet can provide can absorb mechanical shocks
and thereby provide acoustic isolation to the microphone circuit.
As such, the grommet is preferably configured to extend between the printed
circuit board and the housing and encloses the microphone therein, thereby
providing acoustic isolation and a columnated RF signal shield which
extends continuously between the housing and the printed circuit board.
An additional aspect of the present invention is a radiotelephone
microphone shield grommet. The grommet preferably comprises a conductive
flexible cylindrical body with opposing first and second ends and defining
a longitudinal passage therebetween. The grommet is configured to be
operably associated with an electrical ground contact. Preferably, the
first end includes a circumferentially extending continuous ridge
therearound. The radiotelephone microphone shield grommet passage is
configured to receive a radiotelephone microphone therein and preferably
is sized to contact and firmly hold the microphone to thereby acoustically
and electrically shield a radiotelephone microphone from undesired signal
distortions.
The foregoing and other objects and aspects of the present invention are
explained in detail in the specification set forth below.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a greatly enlarged fragmentary section view of a radiotelephone
according to the present invention.
FIG. 2 is a perspective view of a grommet positioned in a radiotelephone
housing according to the present invention.
FIG. 3 is an end view of the grommet in FIG. 2.
FIG. 4 is a sectional view of the grommet illustrated in FIG. 3.
FIG. 5 is a greatly enlarged partial cut away view of a radiotelephone
according to the present invention.
DESCRIPTION OF PREFERRED EMBODIMENTS
The present invention will now be described more fully hereinafter with
reference to the accompanying figures, in which preferred embodiments of
the invention are shown. This invention may, however, be embodied in many
different forms and should not be construed as limited to the embodiments
set forth herein. Like numbers refer to like elements throughout. The
thickness of layers and regions have be exaggerated for clarity.
In the description of the present invention that follows, certain terms are
employed to refer to the positional relationship of certain structures
relative to other structures. As used herein, the term "longitudinal" and
derivatives thereof refer to the general direction defined by the
longitudinal axis of the grommet that extends inwardly between opposing
front and back sides of the radiotelephone when held in the hand of a
user.
Generally described, the present invention is directed towards the
shielding of the radiotelephone input signal path, and in particular to
the circuit path between the far end of the microphone, i.e., the end
adjacent the housing, and the printed circuit board in the housing. As
shown in FIG. 1, the radiotelephone 10 includes a housing 15, a grommet
25, a microphone 35, and a printed circuit board 45. The housing 15
includes at least one opening 17 which is formed therethrough. As is well
known in the art, the opening(s)17 is positioned on the housing 15 to be
in close communication with a user's mouth during operation. This opening
17 allows the sound waves associated with a user's speech to freely enter
the microphone 35.
As illustrated, the housing also includes a pair of opposing and
longitudinally extending fingers 18a, 18b. These fingers 18a, 18b help
align the grommet 25 and the microphone 35 with the underlying printed
circuit board 45. Of course, alternatively configured shapes such as
cylindrical extensions, as well as separate brackets or retainers can also
be employed to facilitate the alignment of the grommet 25 in the housing.
The microphone 35 includes signal and ground contact portions, typically a
central signal contact portion and a circumferentially extending edge
ground contact portion (not shown) and is operably associated with the
printed circuit board 45. Similarly, the printed circuit board 45 includes
a signal contact portion 45a and ground contact portion 45b. As shown, the
microphone 35 and the printed circuit board 45 are connected via a
connector 55. In a preferred embodiment, as is known to those of skill in
the art, the connector is an elastomer connector 55 and includes a series
of conductive carbon or gold fibers surrounded by a non-conducting
material. The fibers are arranged inward of the outer perimeter so as to
allow the connector 55 to conduct the live signal from the microphone
along the "Z" axis, that is, along a path which is defined perpendicular
to the vertical axis in and out of the paper, i.e, the depth plane. of
course, alternative connectors and connection techniques are well known to
those of skill in the art. The connector 55 then relays the live signal to
the signal contact on the printed circuit board 45a.
The grommet 25 is preferably configured to enclose the microphone 35
therein. Further, it is preferred that both ends of the grommet 25a, 25b
are configured to be in continuous contact with the respective mating
surfaces. For example, in a preferred embodiment, as illustrated in FIG.
4, the printed circuit board end 25b of the grommet preferably includes a
circumferentially extending ridge 90. Thus, upon assembly, the ridge 90
can be compressed against the printed circuit board 45 to provide a tight
connection therebetween. The ridge 90 is preferably aligned with and
connected to mating continuous circumferential ground contact(s) 45b on
the printed circuit board 45. This type of contact can facilitate
isolation of the input signal and thereby electrically shield the signal
path from RF distortion.
As illustrated in FIGS. 1 and 5, the grommet 25 preferably extends the
entire distance from the printed circuit board 45 to the housing opening
17. This full length extension provides a columnated shield, i.e., a
continuous longitudinally extending shield which extends around the
microphone 35 from the printed circuit board 45 to the receiving end of
the microphone 35a. Alternatively, the grommet 25 can be sized and
configured to be recessed a predetermined distance from the microphone
receiving end 35a, be flush with the microphone end 35a, or indeed extend
beyond the microphone such that the microphone 35 is recessed therein.
Preferably, the grommet 25 also encloses the connector 55 therein to help
prevent errant RF energy from finding its way into the signal path. As
described above, the outer perimeter of the elastomer connector is
non-conducting such that the signal and ground on the microphone is not
short-circuited by contact with the conductive grommet. Advantageously, in
this embodiment, the grommet 25 encloses both the connector and microphone
in its protective passage 80. It is also preferred that the grommet 25 be
sized and configured to tightly hold the microphone 35 against the mating
components to prevent shaking or movement of the microphone 35. Further
advantageously, this embodiment can reduce acoustic noises or acoustically
isolate and protect the input signal path against aberrant sounds or
distortions that might be introduced by movement or rattling of
components, especially those positioned adjacent the microphone 35,
thereby providing a grommet which can electrically shield and acoustically
isolate the microphone. Thus, preferably the grommet is flexible and
compliant and can advantageously protect the acoustic circuit from
potentially damaging mechanical shocks which may be introduced to the
radiotelephone.
Turning to FIGS. 2-4, a preferred embodiment of the grommet 25 is
illustrated in more detail. Preferably, the grommet 25 is an integrally
formed elastomer conductive grommet. A preferred conductive grommet
material is a silver filled silicone such as that manufactured by the
CHOMERICS Division of PARKER SEALS under formulation number 1310. Examples
of additional suitable materials include, but are not limited to, a
conductive thermoplastic elastomer from the RTP Company known as RTP 2799
X66439. Alternatively, a nonconductive grommet can be treated such that it
includes conductive peripheral surfaces. For example, a silver paint
emulsion can be applied over the surfaces of the grommet. The coating will
preferably be applied over substantially all externally exposed surfaces
of the grommet to form a silver coated elastomer which will electrically
shield the microphone circuit as described above. of course, other grommet
configurations can be implemented to provide a continuous electrical
shield. For example, a continuous, flexible conductive braided sheath can
extend between the housing and the printed circuit board around the
microphone.
FIG. 4 illustrates a grommet 25 with a longitudinally extending passage 80.
The passage 80 includes a first portion 80a and a second portion 80b. The
first portion 80a is sized and configured to enclose the microphone 35
while the second portion 80b is sized and configured to enclose the
(smaller) connector 55. As such, the first portion of the passage is
larger than the second portion of the passage 80a, 80b, respectively.
Further preferably, the grommet 25 includes acoustic seals 100. As
illustrated, the seals 100a, 100b are protrusions extending perpendicular
to the longitudinal axis of the grommet 25. Advantageously, these seals
100a, 100b can provide additional structure so as to facilitate a tight
and secure connection from the microphone to the housing to minimize sound
leakage therebetween.
As will be appreciated by those of skill in the art, one or more of the
above described aspects of the present invention may be provided by
alternative hardware components. For example, the microphone can be any
acoustic to electrical transducer. Additionally, the microphone housing
can include additional discrete components positioned in the microphone
housing. Similarly, the term "printed circuit board" is meant to include
any microelectronics packaging substrate.
The foregoing is illustrative of the present invention and is not to be
construed as limiting thereof. Although a few exemplary embodiments of
this invention have been described, those skilled in the art will readily
appreciate that many modifications are possible in the exemplary
embodiments without materially departing from the novel teachings and
advantages of this invention. Accordingly, all such modifications are
intended to be included within the scope of this invention as defined in
the claims. In the claims, means-plus-function clause are intended to
cover the structures described herein as performing the recited function
and not only structural equivalents but also equivalent structures.
Therefore, it is to be understood that the foregoing is illustrative of
the present invention and is not to be construed as limited to the
specific embodiments disclosed, and that modifications to the disclosed
embodiments, as well as other embodiments, are intended to be included
within the scope of the appended claims. The invention is defined by the
following claims, with equivalents of the claims to be included therein.
* * * * *
|
|
|
|
|
|
|
Description |
|
