JP2012526498A5 - - Google Patents

Description

  In an embodiment of the present invention, a design, manufacture, and operating mechanism for a diaphonic delivery device is also disclosed. This device works with existing balanced armature sound transducers of the type currently used in hearing aids and high performance audio earphones. Alternatively, the device can also work with existing moving coil speakers of the type currently used in headphones, headsets, and earphones. The device of the present invention serves as an air pump to inflate the inflatable member in the listener's ear and also allows the transducer to perform the conventional function of reproducing audio material. Inflatable members (bubbles or balloons), when inflated by the diaphonic pump of the present invention, provide a comfortable, adjustable and variable ear seal that works in conjunction with the ear canal for safe, comfortable and rich sounding and sound Results in a variable volume resonance chamber for high fidelity reproduction.
This specification provides the following items, for example.
(Item 1)
A pressure generation system for an ear device,
An electrical signal generator;
A first receiver (acoustic driver) electrically connected to the signal generator, and capable of generating an audio signal in response to an electrical signal received from the signal generator; A first receiver;
A first sound-actuated pump coupled to the first receiver for discharging air from an outlet port in response to an audio signal from the first receiver in a first mode; A first sound-actuated pump capable of:
An inflatable member connected to the outlet port filled with discharged air, wherein the inflatable member is suitable for positioning in a user's ear canal; and
Equipped with a pressure generating system.
(Item 2)
The first sound actuated pump is:
A first substrate and a conical opening, wherein the opening passes through the first substrate and is aligned with the outlet port; and a first substrate and a conical opening ,
An inlet port for directing air to the opening;
An outlet tube 38 fluidly connected by a first end to the constricted end of the conical opening;
The pressure generation system according to item 1, comprising:
(Item 3)
Item 3. The pressure generating system of item 2, further comprising a tube connected to the inlet port.
(Item 4)
Item 4. The pressure generation system according to Item 3, wherein the inlet port passes through the substrate.
(Item 5)
Item 4. The pressure generating system of item 3, wherein the inlet port is proximal to the substrate.
(Item 6)
Item 4. The pressure generating system of item 3, wherein the inlet port is distal to the substrate.
(Item 7)
The first sound actuated pump is:
A plurality of substrates stacked adjacent to each other, each of the plurality of substrates having a conical opening through the substrate, the opening being an outlet of the first sound actuated pump A plurality of substrates aligned with the ports;
An inlet port for directing air to the first opening;
An outlet pipe 38 fluidly connected by a first end to an outlet port of the first sound actuated pump;
The pressure generation system according to item 2, comprising:
(Item 8)
8. The pressure generating system of item 7, further comprising a tube connected to the inlet port.
(Item 9)
Item 9. The pressure generation system according to Item 8, wherein the inlet port passes through the substrate.
(Item 10)
Item 9. The pressure generating system of item 8, wherein the inlet port is proximal to the substrate.
(Item 11)
Item 9. The pressure generating system of item 8, wherein the inlet port is distal to the substrate.
(Item 12)
Item 8. The pressure generation system according to Item 7, wherein the number of substrates is three or less.
(Item 13)
Item 8. The pressure generating system of item 7, further comprising a membrane positioned between adjacent substrates.
(Item 14)
Item 14. The pressure generating system of item 13, wherein the membrane comprises at least one pore.
(Item 15)
Item 15. The pressure generating system of item 14, wherein the at least one pore is offset from the opening of each adjacent substrate.
(Item 16)
16. The pressure generating system of item 15, further comprising a tube connected to the inlet port of the first substrate, the inlet port being proximal to the membrane.
(Item 17)
The pressure generation system of claim 16, wherein the inlet port is proximal to the first substrate.
(Item 18)
Item 17. The pressure generating system of item 16, wherein the inlet port passes through the first substrate.
(Item 19)
Item 2. The pressure generating system of item 1, further comprising a routing manifold connected to the first sound actuated pump and the expandable member to control expansion and contraction of the expandable member.
(Item 20)
Item 3. The pressure generating system of item 2, further comprising a routing manifold connected to the inlet port, the outlet tube 38, and the expandable member to control expansion and contraction of the expandable member.
(Item 21)
The routing manifold includes an inflation mode in which air is directed from the periphery to the inlet port and from the outlet tube 38 to the inflatable member, the inflatable member to the inlet port, and from the outlet tube 38 to the periphery. Item 21. The pressure generation system of item 20, wherein operation can be switched between a contraction mode in which air is directed.
(Item 22)
A second receiver (acoustic driver) electrically connected to the signal generator, wherein the second receiver is responsive to the electrical signal received from the signal generator to generate an audio output signal; The pressure generation system according to item 1, wherein the pressure generation system is capable of generating
(Item 23)
Item 23. The pressure generation system of item 22, wherein the second receiver (acoustic driver) is connected to an acoustic tube that directs an audio output signal of the second receiver.
(Item 24)
24. The pressure generating system according to item 23, wherein the inflatable member is connected to the outlet port via the acoustic tube.
(Item 25)
24. The pressure generating system according to item 23, wherein the inflatable member is an annular shape defining a passage, and the acoustic tube extends through the passage of the inflatable member.
(Item 26)
Item 2. The pressure generation system according to item 1, further comprising an acoustic tube connecting the expansion member to an outlet port of the first sound-actuated pump.
(Item 27)
27. A pressure generating system according to item 26, wherein the inflatable member is in an annular shape defining a passage, and the acoustic tube extends through the passage in the inflatable member.
(Item 28)
A second receiver (acoustic driver) electrically connected to the signal generator, wherein the second receiver is responsive to the electrical signal received from the signal generator to generate an audio output signal; 27. The pressure generating system of item 26, wherein the pressure generating system is connected to the acoustic tube through which the audio output signal of the second receiver is directed.
(Item 29)
Item 2. The pressure generating system of item 1, wherein the inflatable member is removable from an outlet port of the first sound actuated pump.
(Item 30)
The electrical signal generator, the first receiver (acoustic driver), and the first sound-actuated pump are fixed in a casing, and the inflatable member is detachably connected to the casing. Item 2. The pressure generating pump according to item 1.
(Item 31)
The electrical signal generator, the first receiver (acoustic driver), and the first sound actuated pump are fixed in a housing, and the housing is positioned in the inflatable member. Item 1. The pressure generating pump according to item 1.
(Item 32)
The electrical signal generator, the first receiver (acoustic driver), and the first sound actuated pump are fixed in a housing, and the housing is positioned in the passage of the inflatable member. 28. The pressure generating pump according to item 27.
(Item 33)
Item 23. The pressure generating pump of item 22, wherein the second receiver (acoustic driver) is positioned within the inflatable member.
(Item 34)
Item 2. The pressure generating pump of item 1, further comprising an impedance matching configuration.
(Item 35)
35. A pressure generating pump according to item 34, wherein the impedance matching configuration comprises mechanical flexibility of the inflatable member.
(Item 36)
The pressure of item 1, wherein the first sound-actuated pump comprises an operating cycle having an intake stroke and an exhaust stroke, the intake stroke comprising a range of about 60 to about 99% of the operating cycle time. Generating pump.
(Item 37)
38. The pressure generating pump of item 36, wherein the intake stroke comprises about 95% of the operating cycle time.
(Item 38)
40. A pressure generating pump according to item 36, wherein the operating cycle is reversible.
(Item 39)
The pressure generating pump according to item 1, wherein the audio signal from the first receiver has a sawtooth waveform.
(Item 40)
40. The pressure generating pump of item 39, wherein the sawtooth waveform is asymmetric.
(Item 41)
41. A pressure generating pump according to item 40, wherein the sawtooth waveform is reversible.
(Item 42)
Item 2. The pressure generating pump according to item 1, further comprising a pressure sensor connected to the expansion member.
(Item 43)
43. The pressure generating pump of item 42, wherein the pressure sensor is coupled to the first sound actuated pump to regulate delivery.
(Item 44)
Item 2. The pressure generating pump according to Item 1, further comprising a feedback mechanism for controlling expansion of the expansion-type member.
(Item 45)
45. The pressure generating pump according to item 44, wherein the feedback mechanism includes a pressure sensor for determining a pressure in the inflatable member.
(Item 46)
46. The pressure generating pump of item 45, wherein the pressure sensor is coupled to the first sound actuated pump to regulate delivery.
(Item 47)
45. The pressure generating pump of item 44, wherein the feedback mechanism comprises a feedback servo circuit connected to the first sound actuated pump.
(Item 48)
Item 2. The pressure generating pump of item 1, wherein the first sound activated pump is capable of drawing air into the pump through the outlet port in a second mode.
(Item 49)
An insertion-type ear mold for placement in an individual's ear canal,
A deformable housing made of a soft elastic outer material and defining an interior space;
An audio receiver positioned in the internal space, the audio receiver having an audio port opening on a surface of the deformable housing and capturing an audio signal via the audio port Is possible, with a voice receiver,
A processor positioned in the internal space, the processor being electrically coupled to the audio receiver;
A power source located in the internal space, the power source electrically connected to the processor;
An acoustic tube positioned within the interior space, wherein the acoustic tube is electrically connected to the receiver and the deformation is such that a port can be positioned proximate to the eardrum in a user's ear An acoustic tube having said port at one end opening on the surface of the possible housing;
A sound-actuated pump positioned in the internal space, the sound-actuated pump being connected to the receiver and responsive to an audio signal from the first receiver to draw air from an outlet port; A sound-actuated pump that can be discharged;
An inflatable member positioned within the internal space, the inflatable member connected to the outlet port filled with discharged air;
An audio signal received by the audio receiver is directed through the processor to drive the sound activated pump to expand the inflatable member;
Ear mold.
(Item 50)
A housing,
A chamber that is closed on all sides, the chamber being positioned within the housing, the side of the chamber comprising a diaphragm having an opening, the side extending through the surface of the housing A chamber including an outlet port to
An inlet port defined in a surface of the housing;
An actuator coupled to the diaphragm, the operation of the actuator causing an oscillating motion of the diaphragm; and
A sound-actuated pump.
(Item 51)
51. A sound-operated pump according to item 50, wherein the oscillating motion of the diaphragm is symmetrical.
(Item 52)
51. A sound-operated pump according to item 50, wherein the oscillating motion of the diaphragm is asymmetric.
(Item 53)
53. A sound actuated pump according to item 52, wherein the oscillating motion of the diaphragm is reversible.
(Item 54)
52. A sound activated pump according to item 51, wherein the opening is conical.
(Item 55)
53. A sound operated pump according to item 52, wherein the opening is conical.
(Item 56)
51. A sound operated pump according to item 50, wherein the actuator comprises one of a balanced armature or a moving coil speaker.
(Item 57)
51. A sound operated pump according to item 50, further comprising a check valve at the inlet port.
(Item 58)
51. A sound operated pump according to item 50, further comprising a check valve at the outlet port.
(Item 59)
58. A sound operated pump according to item 57, further comprising a check valve at the outlet port.
(Item 60)
58. The check valve is a flexible membrane attached within the housing at the inlet port, the flexible membrane having an opening offset from the inlet port. Sound operated pump.
(Item 61)
51. A sound operated pump according to item 50, further comprising a check valve at the opening of the chamber.
(Item 62)
A housing defining an internal chamber;
A membrane having an opening, the membrane extending across the internal chamber, thereby dividing the chamber into first and second subchambers; and
A first flow port extending from the wall of the first subchamber;
A second flow port extending from the wall of the second subchamber;
A first transducer acoustic wave delivered to the first sub-chamber in a first phase;
A second transducer acoustic wave delivered to the second sub-chamber in a second phase;
With
The first phase of the first sound wave and the second phase of the second sound wave are from one of the first or second flow ports to the first or second flow port. Manipulated to produce a net fluid flow towards the other of the
Sound operated pump.
(Item 63)
63. A sound operated pump according to item 62, wherein the fluid flow is reversible.
(Item 64)
63. A sound actuated pump according to item 62, wherein the manipulated first phase and second phase generate an oscillating motion of the membrane.
(Item 65)
65. A sound operated pump according to item 64, wherein the oscillating motion of the membrane is symmetric.
(Item 66)
65. A sound actuated pump according to item 64, wherein the oscillating motion of the membrane is asymmetric.
(Item 67)
70. A sound operated pump according to item 66, wherein the asymmetric vibration motion of the diaphragm is reversible.
(Item 68)
63. A sound operated pump according to item 62, wherein the opening of the membrane is conical.
(Item 69)
66. A sound operated pump according to item 65, wherein the opening of the membrane is conical.
(Item 70)
The first transducer sound wave is produced by a first transducer connected to the first sub-chamber and the second transducer sound wave is produced by a second transducer connected to the second sub-chamber. The sound-operated pump according to item 62, wherein:
(Item 71)
63. A sound operated pump according to item 62, wherein the first transducer sound wave and the second transducer sound wave are produced by the same transducer.
(Item 72)
72. A sound operated pump according to item 71, further comprising an audio delivery tube coupling the transducer to each of the two sub-chambers to optimize phase difference.
(Item 73)
A diaphonic ear assembly,
A housing having an open end and a closed end;
Pressurizing means coupled to the housing at the closed end, the pressurizing means being capable of delivering fluid in a first direction;
A linear actuator positioned in the housing at the closed end and connected to the pressurizing means in response to the pressurizing means delivering fluid in a first direction; An actuator capable of moving from a position to a second position;
An audio transducer attached to the actuator and positioned within the housing, the transducer having a pump capable of exhausting air through an outlet port;
An acoustic tube coupled to the outlet port of the audio transducer;
A contraction member coupled to the acoustic tube and positioned within the housing, the contraction member being inflatable by the exhausted air, and suitable for positioning in a user's ear canal; When the actuator moves to the second position, the contraction member
A contraction member that is moved out of the housing;
An assembly.
(Item 74)
74. The assembly of item 73, wherein the contraction member automatically expands when moved out of the housing.
(Item 75)
74. An assembly according to item 73, wherein the pressurizing means is capable of delivering fluid in a second direction opposite to the first direction.
(Item 76)
76. The assembly of item 75, wherein the actuator is capable of moving from the second direction to the first direction in response to the pressurizing means delivering fluid in the second direction. .
(Item 77)
77. The assembly of item 76, wherein the contraction member is placed into the housing when the actuator is moved to the first position.
(Item 78)
74. The assembly of item 73, wherein the pressurizing means comprises a sound activated pump.
(Item 79)
74. The assembly of item 73, wherein the housing is cylindrical.
(Item 80)
74. The assembly of item 73, wherein the linear actuator comprises a pneumatic cylinder and a piston that moves within the cylinder.
(Item 81)
76. The assembly of item 75, wherein the pressurizing means is reversible between delivering fluid in the first direction and the second direction.
(Item 82)
The linear actuator further comprises an inflatable skirt attached to the bottom of the piston in the cylinder and a stepped needle valve, the stepped needle valve being connected to the pressurizing means and passing through the skirt. Extending through the bottom port of the piston into the piston, the stepped needle valve having a vent below the end, the diameter of the port past the vent 81. The assembly of item 80, wherein the assembly is larger than the diameter of the needle.
(Item 83)
83. The assembly of item 82, wherein the piston comprises a passage aligned with the port at one end and the contraction member at the other end.
(Item 84)
84. The assembly of item 83, wherein the fluid delivered to the actuator is sent to the contraction member via the passage.
(Item 85)
A method for inflating an audio device for an ear in a user's ear canal, comprising:
Disposing an inflatable member in the user's ear canal, wherein the inflatable member is connected to an electrical signal generator, a power source, and an audio transducer having a sound-actuated pump;
Generating an electrical signal by the electrical signal generator;
Generating an audio signal by the audio transducer in response to the electrical signal;
Activating the pump to operate in a cycle in response to the audio signal, the operating cycle comprising:
Drawing air at the inlet port of the pump;
Exhausting the air from an outlet port of the pump;
Including steps, and
Capturing the discharged air in the inflatable member connected to the outlet port;
Including
The inflatable member expands until the member is secured in the user's ear canal;
Method.
(Item 86)
86. The method of item 85, further comprising transmitting the audio signal to a user's ear (tympanic membrane).
(Item 87)
86. The method of item 85, further comprising: generating a second audio signal in response to the electrical signal; and transmitting the second audio signal to a user's ear (tympanic membrane).
(Item 88)
86. The method of item 85, wherein positioning the inflatable member comprises positioning the member such that an amount of air exists between the member and the user's tympanic membrane.
(Item 89)
The amount of air has a first impedance, air trapped in the inflatable member has a second impedance, and the method further includes matching the first and second impedances. 90. The method of item 88, comprising:
(Item 90)
90. The method of item 89, wherein matching the first and second impedances includes mechanical flexibility of the inflatable member.
(Item 91)
86. The method of item 85, wherein the step of retracting the pump cycle includes a range of about 60 to about 99% of the time of the operating cycle.
(Item 92)
92. The method of item 91, wherein the step of retracting includes approximately 95% of the time of the operating cycle.
(Item 93)
86. The method of item 85, wherein the pump cycle is reversible so as to reverse the air flow entering the outlet port and the air flow exiting the inlet port.
(Item 94)
86. The method of item 85, wherein the generated audio signal for operating the pump comprises a sawtooth waveform, and an operating cycle of the pump corresponds to a cycle of the waveform.
(Item 95)
95. The method of item 94, wherein the sawtooth waveform is asymmetric.
(Item 96)
96. The method of item 95, wherein the asymmetric sawtooth waveform is reversible.
(Item 97)
86. A method according to item 85, further comprising adjusting an operating cycle of the pump.
(Item 98)
The step of adjusting the operating cycle of the pump comprises a pressure sensor coupled to the inflatable member, the sensor being capable of transmitting a signal to modify the audio signal at a predetermined pressure measurement. 98. The method of item 97.
(Item 99)
86. The method of item 85, further comprising a feedback mechanism to control expansion of the expandable member.
(Item 100)
100. The method of item 99, wherein the feedback mechanism comprises a pressure sensor for determining a pressure in the inflatable member.
(Item 101)
100. The method of item 99, wherein the feedback mechanism comprises a feedback servo circuit connected to one of the pump, the electrical signal generator, or the audio transducer.
(Item 102)
A device for transmitting sound to a user's ear,
A first transducer capable of producing an audio signal (tone) in response to the electrical signal;
An electrical signal input connected to the transducer;
An inflatable member having a side wall defining an interior space and configured to be positioned within a user's ear canal;
A first acoustic tube having a side wall and an opposite end, wherein the first acoustic tube is connected to the transducer at one end and connected to the inflatable member at the opposite end, from within the acoustic tube; A first acoustic tube having a passage defined in the acoustic tube to the outside of the acoustic tube, the passage of the acoustic tube being positioned in an interior space of the inflatable member;
Equipped with a device.
(Item 103)
103. A device according to item 102, wherein the passage comprises an opening defined in a side of the acoustic tube.
(Item 104)
104. A device according to item 103, wherein the opening comprises at least one port.
(Item 105)
The acoustic tube is a first tubular section having a diameter, a first tubular section attached to the transducer at one end, and a diameter smaller than the diameter of the first tubular section. A second tubular section, wherein the second tubular section fits within the first tubular section and is disposed from the first tubular section when placed in the user's ear canal. 104. A device according to item 103, which extends toward a user's eardrum.
(Item 106)
The acoustic tube comprises a plurality of spacers disposed between the first tubular section and the second tubular section to create a gap, and the opening further comprises the gap. 106. A device according to item 105.
(Item 107)
105. The device of item 102, wherein the transducer is encapsulated within an interior space of the inflatable member.
(Item 108)
103. A device according to item 102, wherein the acoustic tube is enclosed in an internal space of the inflatable member.
(Item 109)
105. The device of item 102, wherein the acoustic tube comprises a plurality of ports defined in the sidewall.
(Item 110)
110. A device according to item 109, wherein the number of ports ranges from 2 to 12.
(Item 111)
111. A device according to item 110, wherein the number of ports is six.
(Item 112)
112. The device according to item 111, wherein the ports are evenly spaced around the side wall of the tube in a single plane perpendicular to the longitudinal axis of the tube.
(Item 113)
110. The device of item 109, wherein the plurality of ports are spaced around a side wall of the tube in a single plane perpendicular to the longitudinal axis of the tube.
(Item 114)
110. The device of item 109, wherein the plurality of ports are spaced around a side wall of the tube in a plurality of planes perpendicular to the longitudinal axis of the tube.
(Item 115)
113. A device according to item 112, wherein the acoustic tube is enclosed in an internal space of the inflatable member.
(Item 116)
114. A device according to item 113, wherein the acoustic tube is enclosed in an internal space of the inflatable member.
(Item 117)
105. The device of item 102, wherein the transducer produces a first tone and a second tone.
(Item 118)
118. The device of item 117, wherein the first tone and the second tone are produced alternately.
(Item 119)
118. The device of item 117, wherein the first tone and the second tone are produced simultaneously.
(Item 120)
119. Item 118, wherein the transducer comprises a sound operated pump for receiving at least one of the first tone or the second tone and producing airflow in response thereto. Devices.
(Item 121)
103. A device according to item 102, wherein the transducer comprises a sound activated pump for receiving the audio signal and responsively producing an air flow.
(Item 122)
123. The device of item 120, wherein the air flow is directed into the acoustic tube and passes through the passage to inflate the inflatable member.
(Item 123)
123. The device of item 120, wherein the air flow is directed from the user's ear canal into the acoustic tube and through the passage into the inflatable member.
(Item 124)
123. The device of item 120, wherein the air flow is directed from the expansion member through the passage and into the acoustic tube to contract the expansion member.
(Item 125)
121. The device of item 120, wherein the voice pump directs flow in a first direction in response to the first tone and in an opposite direction in response to the second tone.
(Item 126)
103. The device of item 102, further comprising a second transducer connected to the electrical signal input and capable of producing an audio signal (tone) in response to the electrical signal.
(Item 127)
The first transducer includes a sound-actuated pump for inflating the inflatable member in response to the audio signal, and the second transducer is in response to the audio signal, the inflatable member. 127. A device according to item 126, comprising a sound operated pump for deflating the device.
(Item 128)
The second transducer further includes a second acoustic tube coupled to the second transducer at one end and to the inflatable member by an opposite end, and audio signals from the second transducer pass through the acoustic tube through the user's eardrum. 126. A device according to item 126, which is directed to
(Item 129)
And further comprising a length of material having two ends and covering a passage defined in a side wall of the acoustic tube, wherein at least one end of the material is attached to the acoustic tube to form a seal. 105. The device of item 102.
(Item 130)
130. The device according to item 129, wherein an end of the material positioned between the transducer and a passage in a side wall of the acoustic tube is attached to the acoustic tube to form a seal.
(Item 131)
130. A device according to item 129, wherein both ends of the material are attached to the acoustic tube to form a seal.
(Item 132)
134. The device of item 131, wherein the material comprises a port, and the port of material is offset from the passage of the acoustic tube.
(Item 133)
129. The device according to item 129, wherein the material comprises a cylindrical sleeve.
(Item 134)
A sleeve of material having two ends and covering a plurality of ports defined in a sidewall of the acoustic tube, wherein at least one end of the sleeve is attached to the acoustic tube to form a seal; 110. The device according to item 109.
(Item 135)
135. A device according to item 134, wherein both ends of the sleeve are attached to the acoustic tube to form a seal.
(Item 136)
140. The device of item 135, wherein the sleeve comprises a port, and the port of the sleeve is offset from a plurality of ports defined in a side wall of the acoustic tube.
(Item 137)
135. The device of item 134, wherein the transducer comprises a sound activated pump for receiving the audio signal and responsively producing an air flow.
(Item 138)
140. The device of item 137, wherein the air flow is directed from the user's ear canal into the acoustic tube and through the passage into the inflatable member.
(Item 139)
138. The device of item 137, wherein the air flow is directed from the expansion member through the passage and into the acoustic tube to contract the expandable member.
(Item 140)
An air inlet pipe having a first end extending outside the inflatable member and a second end in the internal space of the inflatable member, the air inlet pipe being an internal space of the inflatable member. 135. A device according to any of items 102, 106, 109, 120, 126, 129, or 134 that directs an air flow between and the surroundings.
(Item 141)
141. The device of item 140, wherein the portion of the air inlet tube that includes the second end comprises a channel in a side wall of the acoustic tube.
(Item 142)
142. The device according to Item 141, wherein the second end is positioned adjacent to a passage in a side wall of the acoustic tube.
(Item 143)
142. The device of item 141, further comprising a ring manifold fluidly connected to a second end of the air inlet tube.
(Item 144)
144. The device of item 143, further comprising at least one air delivery tube fluidly connected to the ring manifold.
(Item 145)
145. The device of item 144, wherein the at least one air delivery tube has an end positioned adjacent to a passage in a side of the acoustic tube.
(Item 146)
146. The device of item 145, wherein the number of air delivery tubes corresponds to the number of ports defined on the side of the acoustic tube.
(Item 147)
144. The device of item 143, wherein the ring manifold is positioned at a base of the acoustic tube connected to the transducer.
(Item 148)
144. The device of item 143, wherein the ring manifold is positioned on the acoustic tube adjacent to the passage.
(Item 149)
And an air inlet tube having a first end extending outside the inflatable member and a second end in the interior space of the inflatable member, the air inlet tube including the inflatable member and the periphery. 123. The device of item 120, wherein the air flow is directed between and the air flow generated by the voice pump has a pressure greater than a line resistance in the air inlet tube.
(Item 150)
150. The device of item 149, wherein air pressure in the inflatable member and in the user's ear canal is balanced by the air inlet tube.
(Item 151)
103. The device of item 102, wherein the transducer is coupled to the acoustic tube outside the inflatable member.
(Item 152)
A plurality of ports defined in a side wall of the acoustic tube;
A sound-operated pump in the transducer for producing an air flow in response to an audio signal;
A sleeve of material having two ends and covering a plurality of ports defined in a side wall of the acoustic tube, wherein at least one end of the sleeve is attached to the acoustic tube to form a seal. The sleeve and
An air inlet tube having a first end extending outside the inflatable member and a second end in the interior space of the inflatable member, the air inlet tube comprising the inflatable member and the periphery An air inlet pipe that directs the air flow between
151. The device of item 151, further comprising:
(Item 153)
153. The device according to item 152, further comprising a ring manifold fluidly connected to a second end of the air inlet tube.
(Item 154)
105. The device of item 102, wherein the transducer is partially contained within an interior space of the inflatable member.
(Item 155)
A plurality of ports defined in a side wall of the acoustic tube;
A sound-operated pump in the transducer for producing an air flow in response to an audio signal;
A sleeve of material having two ends and covering a plurality of ports defined in a side wall of the acoustic tube, wherein at least one end of the sleeve is attached to the acoustic tube to form a seal. The sleeve and
An air inlet tube having a first end extending outside the inflatable member and a second end in the interior space of the inflatable member, the air inlet tube comprising the inflatable member and the periphery An air inlet pipe that directs the air flow between
The device of item 154, further comprising:
(Item 156)
156. The device of item 155, further comprising a ring manifold fluidly connected to a second end of the air inlet tube.
(Item 157)
An air inlet tube for directing an air flow between the inflatable member and the surroundings, the air inlet tube comprising:
A first end extending outside the inflatable member;
A second end in the interior space of the inflatable member;
At least one groove defined in a side wall of the acoustic tube and fluidly connected to the second end at one end;
105. The device of item 102, comprising:
(Item 158)
158. The device of item 157, wherein the transducer and the acoustic tube are positioned within an interior space of the inflatable member.
(Item 159)
158. The device of item 157, wherein the transducer is positioned on an exterior of the inflatable member and the acoustic tube passes through a wall of the inflatable member.
(Item 160)
158. The device of item 157, wherein the transducer is partially encapsulated within the inflatable member.
(Item 161)
158. The device of item 157, wherein an end of the groove is positioned adjacent to a passage in a side wall of the acoustic tube.
(Item 162)
Item 161 further comprising a sleeve of material having two ends and covering a passageway in a side wall of the acoustic tube, wherein at least one end of the sleeve is attached to the acoustic tube to form a seal. Device described in.
(Item 163)
163. A device according to Item 162, wherein both ends of the sleeve are attached to the acoustic tube to form a seal.
(Item 164)
164. The device of item 163, wherein the sleeve comprises a port, and the port of the sleeve is offset from a passage in a side wall of the acoustic tube.
(Item 165)
163. A device according to item 157 or 162, further comprising a ring manifold that fluidly connects a second end of the air inlet tube to an end of the groove.
(Item 166)
166. The device of item 165, wherein the acoustic tube comprises a plurality of ports defined in the side wall and a plurality of grooves fluidly connected through the ring manifold to a second end of the air inlet tube.
(Item 167)
166. The device of item 166, wherein the number of grooves corresponds to the number of ports defined in a side wall of the acoustic tube.
(Item 168)
166. The device of item 165, wherein the ring manifold is positioned at a base of the acoustic tube connected to the transducer.
(Item 169)
166. The device of item 165, wherein the ring manifold is positioned on the acoustic tube adjacent to a passage in the acoustic tube.
(Item 170)
168. The device of item 167, wherein the number of ports and the number of grooves are in the range of 2 to 12.
(Item 171)
171. The device of item 170, wherein the number of ports and the number of grooves are six.
(Item 172)
170. A device according to item 170, wherein the grooves are arranged in a spiral on the outer surface of the acoustic tube.
(Item 173)
173. The device of item 172, wherein the spirally arranged grooves form one of a right helix, a left helix, or both.
(Item 174)
A device for transmitting sound to a user's ear,
A first transducer capable of producing an audio signal (tone) in response to the electrical signal;
An electrical signal input connected to the transducer;
An inflatable member having a side wall defining an interior space and configured to be positioned within a user's ear canal;
A first acoustic tube having a side wall and two opposing ends, the first acoustic tube being connected to the transducer at one end and open at an opposite end in the interior space of the inflatable member; A first acoustic tube having a passage in the side wall, the passage being positioned in an internal space of the inflatable member;
An air inlet pipe having a first end extending outside the inflatable member and a second end in the inner space of the inflatable member, wherein the air inlet pipe is an inner space of the inflatable member. An air inlet tube that directs the air flow between the
Equipped with a device.
(Item 175)
175. The device of item 174, wherein the passage comprises at least one port defined in the sidewall.
(Item 176)
174. The device of item 175, wherein the number of ports ranges from 2 to 12.
(Item 177)
179. The device of item 176, wherein the number of ports is six.
(Item 178)
180. The device of item 177, wherein the ports are evenly spaced around the side wall of the tube in a single plane perpendicular to the longitudinal axis of the tube.
(Item 179)
175. The device according to item 174, wherein the transducer produces a first tone and a second tone.
(Item 180)
179. The device of item 179, wherein the first tone and the second tone are produced alternately.
(Item 181)
180. The device of item 179, wherein the first tone and the second tone are produced simultaneously.
(Item 182)
182. Item 181 wherein the transducer comprises a sound operated pump for receiving at least one of the first tone or the second tone and producing airflow in response thereto. Devices.
(Item 183)
174. The device of item 174, wherein the transducer comprises a sound activated pump for receiving the audio signal and responsively producing an air flow.
(Item 184)
184. The device of item 183, wherein the voice pump directs flow in a first direction in response to the first tone and in an opposite direction in response to the second tone.
(Item 185)
A sleeve of material having two ends and covering a plurality of ports defined in a sidewall of the acoustic tube, wherein at least one end of the sleeve is attached to the acoustic tube to form a seal; 174. The device of item 175.
(Item 186)
186. A device according to item 185, wherein both ends of the sleeve are attached to the acoustic tube to form a seal.
(Item 187)
187. The device of item 186, wherein the sleeve comprises a port, and the port of the sleeve is offset from a plurality of ports defined in a sidewall of the acoustic tube.
(Item 188)
175. The device according to item 174, wherein a portion of the air inlet tube comprises a channel in a side wall of the acoustic tube.
(Item 189)
175. The device of item 174, further comprising a ring manifold fluidly connected to the air inlet tube.
(Item 190)
189. The device of item 189, wherein the air inlet tube comprises a plurality of air delivery tubes fluidly connected to the ring manifold.
(Item 191)
175. The device of one of items 102 or 174, further comprising a coupling mechanism to removably connect the acoustic tube to the transducer.
(Item 192)
196. A device according to item 191, wherein the coupling mechanism comprises a locking mechanism for securing the acoustic tube to the transducer when coupled.
(Item 193)
The coupling mechanism includes a first component attached to the transducer and a second component attached to the acoustic tube, and the first and second components are connectable. 191. A device according to item 191, wherein
(Item 194)
196. The device of item 191, wherein the acoustic tube comprises an air inlet tube that terminates adjacent to the coupling mechanism outside the interior space of the inflatable membrane.
(Item 195)
The connecting mechanism includes a first ring having an inner periphery and a second ring having an outer periphery, and the outer periphery of the second ring fits within the inner periphery of the first ring. The device described.
(Item 196)
196. The device of item 195, wherein the first and second rings are coded to indicate a particular characteristic of the device.
(Item 197)
196. The device according to item 196, wherein the first and second rings are color coded.
(Item 198)
196. The device according to item 196, wherein the first and second rings are encoded with a key.
(Item 199)
196. The device of item 197, wherein the first and second rings are encoded with a key.
(Item 200)
195. The device of item 196, wherein one of the first or second rings is made of a rigid material and the other of the first or second rings is made of a flexible material.
(Item 201)
196. The device of item 196, wherein the second ring friction fits within the first ring.
(Item 202)
The second ring is threaded around the outer periphery, and the first ring is threaded correspondingly around the inner periphery, allowing the ring to be threadably engaged. 196. The device of item 196.
(Item 203)
175. The device of any of items 102 or 174, further comprising an external audio device coupled to the acoustic tube, wherein the external audio device expands or contracts the inflatable member by emitting a tone.
(Item 204)
204. The device of item 203, further comprising a valve for closing the acoustic tube during expansion or contraction of the expandable member.
(Item 205)
204. A device according to item 203, wherein the tone includes an activation tone during inflation.
(Item 206)
204. A device according to item 203, wherein the tone comprises a stop tone during contraction.
(Item 207)
204. A device according to item 203, wherein the tone is inaudible.
(Item 208)
175. The device according to any of items 102 or 174, further comprising an external pump for inflating the inflatable member.
(Item 209)
209. The device of item 208, wherein the external pump operates to contract the inflatable member.
(Item 210)
209. The device of item 208, wherein the external pump comprises a syringe pump.
(Item 211)
209. The device of item 209, wherein the external pump comprises a syringe pump.
(Item 212)
209. The device of item 208, wherein the external pump comprises a diaphragm pump.
(Item 213)
209. The device of item 209, wherein the external pump comprises a diaphragm pump.
(Item 214)
209. The device of item 208, wherein the external pump is manually operated.
(Item 215)
209. The device of item 209, wherein the external pump is manually operated.
(Item 216)
175. The device of any of items 102 or 174, further comprising feedback control to overcome a loss of sealing in the user's ear canal.
(Item 217)
227. A device according to item 216, wherein the feedback control comprises hardware (electronic equipment).
(Item 218)
The device of item 216, wherein the feedback control comprises software.
(Item 219)
227. The device of item 216, wherein the feedback control comprises an audio signal that increases air flow to the inflatable member.
(Item 220)
175. A device according to any of items 102 or 174, wherein the inflatable member comprises an outer wall and an inner wall at least partially sealed to the outer wall to contain a quantity of air.
(Item 221)
224. The device of item 220, wherein the inflatable member further comprises spacer ribs connecting the outer wall to the inner wall.
(Item 222)
224. The device of item 221, wherein the spacer ribs are disposed longitudinally within the inflatable member.
(Item 223)
224. The device of item 221, wherein the spacer rib is disposed laterally within the inflatable member.
(Item 224)
224. The device of item 221, wherein the spacer ribs are helically disposed within the inflatable member.
(Item 225)
220. The device of item 220, wherein the transducer is positioned within an interior space of the inflatable member.
(Item 226)
223. The device of item 220, wherein at least one of the outer wall and the inner wall is made of an anisotropic material.
(Item 227)
220. The device of item 220, wherein at least one of the outer wall and the inner wall is made of an isotropic material.
(Item 228)
227. The device of item 227, wherein one of the outer wall and the inner wall is made of an anisotropic material.
(Item 229)
213. The device of item 220, wherein the inflatable member is coated with a material to optimize selected functional properties.
(Item 230)
229. The device of item 229, wherein the coating material comprises a polymer latex.
(Item 231)
The device of item 230, wherein the polymer latex comprises a polyurethane latex.
(Item 232)
242. The device of item 231, wherein the polyurethane latex is water soluble.
(Item 233)
229. The device of item 229, wherein the coating material comprises fumed silica.
(Item 234)
229. The device of item 229, wherein the inflatable member is coded to correspond to optimized functional characteristics.
(Item 235)
231. The device according to item 230, wherein the inflatable member is color coded to correspond to optimized functional characteristics.
(Item 236)
229. The device of item 229, wherein a rear section of the inflatable member is coated to optimize sound transmission interruption.
(Item 237)
229. The device of item 229, wherein an intermediate section of the inflatable member is coated to optimize sealing properties.
(Item 238)
229. The device of item 229, wherein a front section of the inflatable member is coated to optimize acoustic properties.
(Item 239)
229. The device of item 229, wherein an outer surface of the inflatable member is coated to provide optimized properties in gradients.
(Item 240)
213. The device of item 220, wherein at least one of the outer wall and the inner wall is comprised of expanded polytetrafluoroethylene (ePTFE).
(Item 241)
The device of item 240, wherein the expanded polytetrafluoroethylene is injected with polyurethane latex.
(Item 242)
213. The device of item 220, wherein at least one of the outer wall and the inner wall is made of polyurethane.
(Item 243)
220. The device of item 220, wherein the inflatable member comprises a closed convex bubble shape.
(Item 244)
The device of item 220, wherein the outer and inner walls have a thickness of less than about 10 mils (0.254 mm).
(Item 245)
254. The device of item 244, wherein the outer wall and the inner wall have a thickness of less than about 3 mil (0.0762 mm).
(Item 246)
254. The device of item 244, wherein the outer wall and the inner wall have a thickness of less than about 1 mil (0.0254 mm).
(Item 247)
The device of item 220, wherein the outer and inner walls are made of a material having low air permeability.
(Item 248)
248. The device of item 247, wherein the material comprises pores having a diameter in the range of about 0.5 to about 1.0 microns.
(Item 249)
248. The device of item 247, wherein the material comprises pores having a diameter of only about 0.5 microns.
(Item 250)
An inflatable member having an interior space defined by a surface; and a ferrule attached to the surface within the interior space;
An acoustic tube having first and second ends and positioned in the internal space, the acoustic tube connected to the ferrule at one end;
A coupler connected to an end of the acoustic tube, the coupler having an elastic band connecting the coupler to the inflatable member;
A pressure tube open at each end, a pressure tube passing through the coupler from the outside of the inflatable member to the internal space of the inflatable member;
An ear device comprising:
(Item 251)
A receiver assembly;
A housing,
A channel having a port that passes through the housing and connects to an end of the pressure tube outside the inflatable member;
A voice port detachably connected to the coupler;
A receiver positioned in the housing and connected to the voice port;
An electrical and pressure interface port extending from the housing, the electrical and pressure interface port for connecting to an audio device;
251. An ear device according to item 250, comprising:
(Item 252)
251. The ear device of item 251, wherein the audio device is a hearing aid.
(Item 253)
251. The aural device of item 251, further comprising a pump assembly removably connected to the electrical and pressure interface port.
(Item 254)
251. The aural device of item 251, further comprising a processor removably connected to the electrical and pressure interface port.
(Item 255)
106. The device of item 105, wherein the second tubular section is retractable into the first tubular section.
(Item 256)
108. The device of item 106, further comprising a polymer sleeve having a first end in contact with the first tubular section and a second end in contact with the second tubular section.
(Item 257)
256. The device according to item 256, wherein the sleeve forms a seal with the first tubular section.
(Item 258)
256. The device according to item 256, wherein the sleeve forms a seal with the second tubular section.
(Item 259)
258. The device of item 257, wherein the sleeve forms a seal with the second tubular section.
(Item 260)
The device of item 259, wherein the sleeve comprises a port.
(Item 261)
175. A device according to item 102, 105, 151, 154, or 174, further comprising a coupler attached to the acoustic tube for removably connecting the inflatable member to the transducer.
(Item 262)
268. The device of item 261, wherein the coupler comprises a locking mechanism.
(Item 263)
Item 261, wherein the coupler comprises a first portion attached to the acoustic tube and a second portion attached to the acoustic tube, the two portions being correspondingly encoded. Device described in.
(Item 264)
264. The device of item 263, wherein the portion of the coupler is color coded.
(Item 265)
268. The device according to item 263, wherein the part is encoded with a key.
(Item 266)
An outer housing that defines a front volume in the outer housing;
An inner housing that is in the outer housing and surrounds a rear volume;
A balanced armature positioned within the inner housing;
An electrical coil around one arm of the armature, wherein the current through the coil causes vibration of the arm;
A flexible diaphragm positioned in a wall of the inner housing, wherein the flexible diaphragm is coupled to the arm so as to separate the front volume and the rear volume and vibrate in unison with the arm; Sex diaphragm,
An equalization port defined in a wall of the inner housing;
An inlet port defined in a wall of the outer housing, the inlet port for drawing air into the housing;
An outlet port defined in a wall of the outer housing, the outlet port for exhausting air from the housing;
With
Vibration of the diaphragm causes fluid flow into the inlet port, through the equalization port, and out of the outlet port;
Balanced armature transducer pump.
(Item 267)
268. The balanced armature transducer pump of item 266, wherein the equalization port is positioned within the diaphragm.
(Item 268)
268. The balanced armature transducer pump of item 267, wherein the equalization port comprises a conical depression.
(Item 269)
268. The balanced armature transducer pump of item 266, wherein the armature arm vibrates with an asymmetric waveform.
(Item 270)
268. The balanced armature transducer pump of item 268, wherein the armature arm vibrates with an asymmetric waveform.
(Item 271)
268. The balanced armature transducer pump of item 269, wherein the waveform has a rising portion that is longer than a falling portion.
(Item 272)
281. The balanced armature transducer pump of item 271, wherein the waveform is reversible.
(Item 273)
275. The balanced armature transducer pump of item 266, further comprising a flap valve covering the inlet port, the flap valve preventing air from reversing through the port.
(Item 274)
275. The balanced armature transducer pump of item 266, further comprising a coaxial diaphonic valve positioned within the inlet port.
(Item 275)
268. The balanced armature transducer pump of item 267, further comprising a coaxial diaphonic valve positioned within the inlet port.
(Item 276)
268. The balanced armature transducer pump of item 266, further comprising a diaphonic valve positioned within the rear volume of the inner housing.
(Item 277)
268. The balanced armature transducer pump of item 266, further comprising a space filling material in the rear volume of the inner housing.
(Item 278)
268. The balanced armature transducer pump of item 266, further comprising a partition in the rear volume positioned between the diaphragm and the balanced armature.
(Item 279)
279. The balanced armature transducer pump of claim 278, wherein the inlet port is on the wall of the housing on the diaphragm side of the partition.
(Item 280)
268. The balanced armature transducer pump of item 266, wherein the diaphragm is connected to the arm via a pin.
(Item 281)
A housing having an opening defined in the housing;
A first substrate positioned within the housing, the substrate having an orifice through the substrate, the orifice being aligned with an opening of the housing; A substrate;
An inlet tube having a first end positioned proximate to the orifice, a body passing through the housing, and a second end open to the periphery;
A coupler attached to the sound source;
A passage providing fluid communication between a sound source mounted at the coupler and the orifice of the substrate;
A sound-actuated pump.
(Item 282)
281. A sound activated pump according to item 281, wherein the orifice has a conical shape proximal to the passage.
(Item 283)
281. A sound actuated pump according to item 281, wherein the inlet tube passes through the first substrate.
(Item 284)
281. A sound operated pump according to item 281 wherein the inlet tube is distal to the first substrate.
(Item 285)
281. A sound activated pump according to item 281, wherein the inlet tube is proximal to the first substrate.
(Item 286)
281. The sound operated pump of item 281 further comprising an outlet tube positioned in the opening of the housing proximate to the orifice and extending from the housing.
(Item 287)
289. The sound operated pump of item 286, further comprising a tube that is coaxial with the outlet tube and suitable for connection to an inflatable member.
(Item 288)
And further comprising a second substrate positioned within the housing proximal of the first substrate, the second substrate having an orifice through the second substrate, the orifice being 281. The sound operated pump of item 281, aligned with the orifice of the first substrate.
(Item 289)
289. A sound operated pump according to item 288, wherein the inlet tube passes through the second substrate.
(Item 290)
289. A sound operated pump according to item 288, wherein the inlet tube is proximal to the second substrate.
(Item 291)
289. The sound operated pump of item 288, further comprising a membrane positioned between the first and second substrates, the membrane having at least one orifice defined in the membrane.
(Item 292)
281. A sound operated pump according to item 281 further comprising a sound source fluidly coupled to the coupler.
(Item 293)
309. A sound operated pump according to item 292, wherein the sound source produces an acoustic wave that produces static pressure at a distal end of an orifice of the substrate.
(Item 294)
A method of producing static pressure using acoustic vibration,
Providing a sound source fluidly coupled to a housing comprising:
The housing is
An opening through the housing;
A substrate having an orifice in the substrate, wherein the orifice is aligned with an opening of the housing;
An inlet tube, the inlet tube having a first end positioned proximate to the orifice and a second end open to the periphery;
With steps, and
Directing acoustic waves from the sound source in the substrate;
Including a method.
(Item 295)
295. The method of item 294, further comprising attaching an inflatable member at the opening of the housing.
(Item 296)
295. The method of item 294, further comprising attaching an outlet tube at the opening of the housing.
(Item 297)
296. The method of item 296, further comprising attaching an inflatable member to an end of the outlet tube.
(Item 298)
An in-ear device for transmitting sound to the user's ears,
An audio source;
A first transducer coupled to the sound source and capable of generating a static pressure in response to an acoustic signal from the sound source;
A second transducer coupled to the sound source and capable of generating a static pressure in response to an acoustic signal from the sound source;
An inflatable member fluidly coupled to an output of at least one of the first and second transducers;
In-ear device equipped with.
(Item 299)
299. The in-ear device of item 298, wherein the first and second transducers are either balanced armature transducers or moving coil speakers.
(Item 300)
299. The in-ear device of item 298, further comprising an acoustic tube coupling the inflatable member to one of the first transducer, the second transducer, or both.
(Item 301)
299. The in-ear device of item 298, further comprising a diaphonic valve coupled to at least one of the transducers.
(Item 302)
The diaphonic valve is
A first layer defining an inlet channel fluidly coupled to the opening of the transducer housing;
A second layer defining a synjet port fluidly coupled to the inlet channel;
A third layer having a membrane including a flap valve covering the synjet port;
A fourth layer defining an outlet port fluidly coupled to the symjet port;
320. The in-ear device according to item 301, comprising:
(Item 303)
299. The in-ear device of item 298, wherein the first and second transducers are fully encapsulated within the inflatable member.
(Item 304)
404. The in-ear device of item 303, wherein the sound source is completely enclosed within the inflatable member.
(Item 305)
299. The in-ear device of item 298, wherein the first and second transducers are partially encapsulated within the inflatable member.
(Item 306)
306. The in-ear device of item 305, wherein the sound source is partially encapsulated within the inflatable member.
(Item 307)
331. The in-ear device of item 302, wherein the first and second transducers and the diaphonic valve are fully enclosed within the inflatable member.
(Item 308)
330. The in-ear device of item 302, wherein the first and second transducers and the diaphonic valve are partially enclosed within the inflatable member.
(Item 309)
The diaphonic valve further comprises fifth and sixth layers positioned between the third layer and the fourth layer;
The fifth layer has a check valve port defined in the fifth layer offset from the flap valve of the third layer;
The sixth layer has a flexible membrane and a check valve port defined in the sixth layer offset from the check valve port of the fifth layer.
In-ear device according to item 302.
(Item 310)
309. The in-ear device of item 309, wherein the symjet port and the check valve port have raised edges.
(Item 311)
An in-ear device for transmitting sound to the user's ears,
An audio source;
A first transducer coupled to the sound source and capable of generating a static pressure in response to an acoustic signal from the sound source;
An inflatable member fluidly coupled to the output of the first transducer;
In-ear device equipped with.
(Item 312)
311. The in-ear device of item 311 further comprising a second transducer coupled to the sound source and capable of generating a static pressure in response to an acoustic signal from the sound source.
(Item 313)
312. The in-ear device of item 311, wherein the first and second transducers are either balanced armature transducers or moving coil speakers.
(Item 314)
312. The in-ear device of item 311 further comprising an acoustic tube coupling the inflatable member to the first transducer.
(Item 315)
311. The in-ear device of item 311 further comprising a diaphonic valve coupled to the first transducer.
(Item 316)
The diaphonic valve is
A first layer defining an inlet channel fluidly coupled to an opening of the housing of the first transducer;
A second layer defining a synjet port fluidly coupled to the inlet channel;
A third layer having a membrane including a flap valve covering the synjet port;
A fourth layer defining an outlet port fluidly coupled to the symjet port;
316. In-ear device according to item 315, comprising:
(Item 317)
311. The in-ear device of item 311, wherein the first transducer is fully encapsulated within the inflatable member.
(Item 318)
309. The in-ear device of item 317, wherein the sound source is completely enclosed within the inflatable member.
(Item 319)
312. The in-ear device of item 311, wherein the first transducer is partially encapsulated within the inflatable member.
(Item 320)
319. The in-ear device of item 319, wherein the sound source is partially encapsulated within the inflatable member.
(Item 321)
319. The in-ear device of item 316, wherein the first transducer and the diaphonic valve are completely enclosed within the inflatable member.
(Item 322)
319. The in-ear device of item 316, wherein the first transducer and the diaphonic valve are partially enclosed within the inflatable member.
(Item 323)
The diaphonic valve further comprises fifth and sixth layers positioned between the third layer and the fourth layer;
The fifth layer has a check valve port defined in the fifth layer offset from the flap valve of the third layer;
The sixth layer has a flexible membrane and a check valve port defined in the sixth layer that is offset from the check valve port of the fifth layer.
316. In-ear device according to item 316.
(Item 324)
323. The in-ear device of item 323, wherein the symjet port and the check valve port have raised edges.
(Item 325)
299. The in-ear device of item 298, wherein the inflatable member comprises a plurality of laterally aligned inflatable tubes.
(Item 326)
325. The in-ear device of item 325, wherein the tubes are sealed together in the longitudinal direction in a three-dimensional elliptical form.
(Item 327)
325. The in-ear device of item 325, wherein the number of inflatable tubes ranges from 4 to 40.
(Item 328)
328. The in-ear device of item 327, wherein the number of inflatable tubes ranges from 6 to 20.
(Item 329)
312. The in-ear device of item 311, wherein the inflatable member comprises a plurality of laterally aligned inflatable tubes.
(Item 330)
329. The in-ear device of item 329, wherein the tubes are sealed together in the longitudinal direction in a three-dimensional elliptical form.
(Item 331)
329. The in-ear device of item 329, wherein the number of inflatable tubes ranges from 4 to 40.
(Item 332)
329. The in-ear device of item 331, wherein the number of inflatable tubes ranges from 6 to 20.

Claims (48)

A pressure generation system for an ear device, the system comprising:
An electrical signal generator;
A first receiver (acoustic driver) electrically connected to the signal generator, and capable of generating an audio signal in response to an electrical signal received from the signal generator; A first receiver;
A first sound-actuated pump coupled to the first receiver for discharging air from an outlet port in response to an audio signal from the first receiver in a first mode; A first sound-actuated pump capable of:
An inflatable member connected to the outlet port filled with exhausted air, the inflatable member comprising an inflatable member suitable for positioning in a user's ear canal Generating system. The first sound actuated pump is:
A first substrate and a conical opening, wherein the opening passes through the first substrate and is aligned with the outlet port; and a first substrate and a conical opening ,
An inlet port for directing air to the opening;
A outlet pipe, the first end and a outlet pipe fluidly connected to the constriction edge of the opening of the conical pressure generating system according to claim 1.   The pressure generation system of claim 2, further comprising a tube connected to the inlet port.   The pressure generation system of claim 3, wherein the inlet port passes through the substrate.   The pressure generation system of claim 3, wherein the inlet port is proximal of the substrate.   The pressure generation system of claim 3, wherein the inlet port is distal of the substrate. The first sound actuated pump is:
A plurality of substrates stacked adjacent to each other, each of the plurality of substrates having a conical opening through the substrate, the opening being an outlet of the first sound actuated pump A plurality of substrates aligned with the ports;
An inlet port for directing air to the first opening;
A outlet pipe and an outlet pipe fluidly connected to the outlet port of the first sound actuated pump by a first end, a pressure generating system of claim 2.   The pressure generation system of claim 7, further comprising a tube connected to the inlet port.   The pressure generation system of claim 8, wherein the inlet port passes through the substrate.   The pressure generation system of claim 8, wherein the inlet port is proximal to the substrate.   The pressure generation system of claim 8, wherein the inlet port is distal to the substrate.   The pressure generation system according to claim 7, wherein the number of substrates is three or less.   The pressure generation system of claim 7, further comprising a membrane positioned between adjacent substrates.   The pressure generation system of claim 13, wherein the membrane comprises at least one pore.   The pressure generation system of claim 14, wherein the at least one pore is offset from the opening of each adjacent substrate.   The pressure generation system of claim 15, further comprising a tube connected to the inlet port of the first substrate, the inlet port being proximal to the membrane.   The pressure generation system of claim 16, wherein the inlet port is proximal to the first substrate.   The pressure generation system of claim 16, wherein the inlet port passes through the first substrate. The pressure generation system of claim 2, further comprising a routing manifold connected to the inlet port, the outlet tube, and the inflatable member to control expansion and contraction of the inflatable member. The routing manifold, from the periphery to the inlet port, and an expansion mode of air directed into the outlet pipe or we said inflatable member, said to said inlet port from the inflatable member, and the outlet tube or al to ambient between the contraction mode the air Ru oriented, it is possible to switch the operation, pressure generating system of claim 19.   The pressure generation system of claim 1, further comprising a routing manifold connected to the first sound actuated pump and the inflatable member to control expansion and contraction of the inflatable member.   A second receiver (acoustic driver) electrically connected to the signal generator, wherein the second receiver is responsive to the electrical signal received from the signal generator to generate an audio output signal; The pressure generation system according to claim 1, wherein   23. The pressure generating system according to claim 22, wherein the second receiver (acoustic driver) is connected to an acoustic tube that directs an audio output signal of the second receiver.   24. The pressure generating system according to claim 23, wherein the inflatable member is connected to the outlet port via the acoustic tube.   24. The pressure generating system of claim 23, wherein the inflatable member is an annular shape defining a passage, and the acoustic tube extends through the passage of the inflatable member.   23. The pressure generating pump according to claim 22, wherein the second receiver (acoustic driver) is positioned in the inflatable member.   The pressure generation system according to claim 1, further comprising an acoustic tube connecting the inflatable member to an outlet port of the first sound actuated pump. 28. The pressure generating system of claim 27 , wherein the inflatable member is an annulus defining a passage, and the acoustic tube extends through the passage of the inflatable member. The electrical signal generator, the first receiver (acoustic driver), and the first sound actuated pump are fixed in a housing, and the housing is positioned in the passage of the inflatable member. The pressure generating pump according to claim 28 . A second receiver (acoustic driver) electrically connected to the signal generator, wherein the second receiver is responsive to the electrical signal received from the signal generator to generate an audio output signal; it is possible to generate a, the second receiver, it audio output signal of the second receiver is connected to the acoustic tube to be directed through pressure generating according to claim 27 system.   The pressure generating system of claim 1, wherein the inflatable member is removable from an outlet port of the first sound actuated pump.   The electrical signal generator, the first receiver (acoustic driver), and the first sound-actuated pump are fixed in a casing, and the inflatable member is detachably connected to the casing. The pressure generating pump according to claim 1.   The electrical signal generator, the first receiver (acoustic driver), and the first sound actuated pump are fixed in a housing, and the housing is positioned in the inflatable member. The pressure generating pump according to claim 1.   The pressure generating pump of claim 1, further comprising an impedance matching arrangement.   35. The pressure generating pump of claim 34, wherein the impedance matching arrangement comprises mechanical flexibility of the inflatable member.   The first sound activated pump comprises an operating cycle having an intake stroke and an exhaust stroke, wherein the intake stroke comprises a range of about 60 to about 99% of the operating cycle time. Pressure generating pump.   37. The pressure generating pump of claim 36, wherein the intake stroke comprises about 95% of the operating cycle time.   38. The pressure generating pump of claim 36, wherein the operating cycle is reversible.   The pressure generating pump of claim 1, wherein the audio signal from the first receiver comprises a sawtooth waveform.   40. The pressure generating pump of claim 39, wherein the sawtooth waveform is asymmetric.   41. The pressure generating pump of claim 40, wherein the sawtooth waveform is reversible.   The pressure generating pump according to claim 1, further comprising a pressure sensor connected to the expansion member.   43. The pressure generating pump of claim 42, wherein the pressure sensor is coupled to the first sound-operated pump to regulate delivery.   The pressure generating pump according to claim 1, further comprising a feedback mechanism for controlling expansion of the expansion-type member.   45. The pressure generating pump according to claim 44, wherein the feedback mechanism includes a pressure sensor for determining a pressure in the inflatable member.   46. The pressure generating pump of claim 45, wherein the pressure sensor is coupled to the first sound actuated pump to regulate delivery.   45. The pressure generating pump of claim 44, wherein the feedback mechanism comprises a feedback servo circuit connected to the first sound actuated pump.   The pressure generating pump of claim 1, wherein the first sound-operated pump is capable of drawing air into the pump through the outlet port in a second mode.