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A nebulizer determines the pressure and flow direction of the receiving gas for atomized liquid. A member of the apparatus is subjected to pressure exerted by the gas. The member is coupled to a bi-directional mechanical-electrical conversion element, such as a piezoelectric element, to form a press

A nebulizer determines the pressure and flow direction of the receiving gas for atomized liquid. A member of the apparatus is subjected to pressure exerted by the gas. The member is coupled to a bi-directional mechanical-electrical conversion element, such as a piezoelectric element, to form a pressure transducer. The member exerts a mechanical loading on the element responsive to the gas pressure to which it is subjected. In one embodiment, the element mechanically vibrates responsive to alternating electrical energization to discharge the liquid into the gas. The electrical admittance of the element is alterable by the mechanical loading applied to the element by the member. The difference between admittances measured in the loaded condition of the element and in an unloaded condition at the selected energization frequency is an indication of the pressure of the gas. By observing whether the magnitude of the admittance in the loaded state is greater or less than that in the unloaded state, the flow direction of the gas may also be determined. Or the flow direction may be determined by observing the changes in admittance as the frequency of the electrical energization is varied. In another embodiment, the piezoelectric element is not energized. The electrical output of the element, when subjected to a mechanical loading from the gas pressure, is used to detect gas pressures and/or as an indication of the gas pressure.

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1. A method for use with a discharging means discharging a fluid substance into a receiving gas, said method determining the pressure of the receiving gas, said method comprising the steps of:(a) placing the discharging means in fluid communication with the receiving gas so that a bidirectional mech

1. A method for use with a discharging means discharging a fluid substance into a receiving gas, said method determining the pressure of the receiving gas, said method comprising the steps of:(a) placing the discharging means in fluid communication with the receiving gas so that a bidirectional mechanical-electrical conversion element is subjected to mechanical loading responsive to the gas pressure of the receiving gas, the element mechanically vibrating responsive to the application of alternating electrical energization to the element, the element having an admittance, the admittance of the element at a given frequency of alternating electrical energization being alterable by a mechanical loading of the element; (b) applying alternating electrical energization to the element at a selected frequency; (c) subjecting the element to mechanical loading responsive to the pressure of the receiving gas; (d) measuring the admittance exhibited by the element in the loaded condition when energized by the electrical energization of the selected frequency; and (e) determining the difference between the admittance measured in step (d) and another value as an indication of the pressure of the receiving gas. 2. The method of claim 1 wherein a pressure transducer comprising said element has a resonance frequency at which the admittance of the element has a peak value and wherein step (b) is further defined as applying alternating electrical energization to the element at the resonance frequency.3. The method of claim 1 wherein a pressure transducer comprising said element has a resonance frequency at which the admittance of the element has a peak value and wherein step (b) is further defined as applying alternating electrical energization to the element at a frequency other than the resonance frequency.4. The method of claim 1 wherein step (c) is further defined as subjecting a member to pressure exerted by the receiving gas, the member exerting a mechanical loading on the element responsive to the gas pressure.5. The method of claim 4 wherein step (c) is further defined as subjecting a member comprising a porous plate, through which fluid is discharged into the receiving gas by the vibratory action of the element, to the pressure exerted by the receiving gas.6. The method of claim 4 wherein step (c) is further defined as subjecting a member comprising a piston for discharging fluid into the receiving gas by the vibratory action of the element to the pressure exerted by the receiving gas.7. The method of claim 1 wherein the bidirectional mechanical-electrical conversion element of the fluid discharging means comprises a piezoelectric element.8. The method of claim 7 wherein step (c) is further defined as exerting the mechanical loading on the piezoelectric element along an axis of vibration of the piezoelectric element.9. The method of claim 7 wherein the piezoelectric element is a ring-like piezoelectric element coupled to said member and wherein step (b) is further defined as applying alternating electrical energization to the element to cause bowing in the member and wherein, in step (c), the pressure of the receiving gas applied to the member also causes bowing of the member.10. The method of claim 4 wherein the bidirectional mechanical-electrical conversion element of the fluid discharging means comprises a bi-morph structure.11. The method of claim 10 wherein said element is a ring-like element and wherein step (b) is further defined as applying alternating electrical energization to the element to cause bowing in the member and wherein, in step (c), the pressure of the receiving gas applied to the member also causes bowing of the member.12. The method of claim 7 wherein the piezoelectric element is a rod-like element for reciprocating a piston in a fluid filled housing.13. The method of claim 1 further including a step (f) of measuring the admittance exhibited by the element in an unloaded condition when energized by the electrical energization of the selected frequency and wherein step (e) is further defined as measuring the difference between the admittance measured in steps (f) and (d) as an indication of the pressure of the receiving gas.14. The method of claim 1 wherein step (e) is further defined as determining the difference between the admittance measured in step (d) and a reference value to obtain the indication.15. The method of claim 14 wherein step (e) is further defined as determining the difference between the admittance measured in step (d) and a value derived from previously measured admittance values obtained in the manner of step (d), and wherein the difference so determined is compared to a reference value to obtain the indication.16. The method of claim 1 wherein step (d) further comprises the steps of applying alternating electrical energization having a desired voltage property which is constant in magnitude to the element; measuring the current through the element; anddetermining the admittance exhibited by the element from the voltage property and the measured current value. 17. The method of claim 1 wherein step (d) comprises the steps of applying alternating electrical energization having a desired current property which is constant in magnitude to the element; measuring the voltage across the element; anddetermining the admittance exhibited by the element from current property and the measured voltage. 18. The method of claim 1 wherein step (d) comprises the steps of measuring the phase shift in the alternating electrical energization as a result of its application to the element and using the phase shift as an indication of the admittance of the element.19. The method of claim 13 wherein at least one of steps (e) and (f) further comprises the steps of applying alternating electric energization having a desired voltage property which is constant in magnitude to the element; measuring the current through the element; and determining the admittance exhibited by the element from the voltage property and the measured current value.20. The method of claim 13 wherein at least one of steps (e) and (f) further comprises the steps of applying alternating electrical energization having a desired current property which is constant in magnitude to the element; measuring the voltage across the element; and determining the admittance exhibited by the element from current property and the measured voltage.21. The method of claim 13 wherein at least one of steps (e) and (f) further comprises the steps of measuring the phase shift in the alternating electrical energization as a result of its application to the element and using the phase shift as an indication of the admittance of the element.22. The method of claim 1 further defined as a method for measuring the pressure of the breathing gases for a subject.23. The method of claim 1 wherein the fluid discharging means comprises a nebulizer.24. The method of claim 22 wherein the fluid discharging means comprises a nebulizer.25. The method of claim 13 further defined as determining a flow direction of the receiving gas, opposite directions of flow of the receiving gas subjecting the fluid discharging means element to differing pressures and subjecting the element to differing mechanical loading, said method further including the steps of:(g) altering frequency of the alternating electrical energization applied to the element to a frequency higher or lower than that applied in step (b); (h) measuring the admittance exhibited by the element in the loaded condition when energized by the electrical energization of altered frequency; (i) determining the difference in the admittances measured in steps (d) and (h); and (j) comparing the difference determined in step (i) with the difference determined in step (e) to determine the direction of flow of the receiving gas. 26. The method of claim 25 wherein step (b) is further defined as applying alternating electrical energization to the element at a resonance frequency.27. The method of claim 13 further defined as subjecting a member to pressure exerted by the receiving gas, the member exerting a mechanical loading on the element responsive to gas pressure, said method being further defined as a method for determining the flow direction of the receiving gas, opposite directions of receiving gas flow subjecting the fluid discharging means member to differing pressures and subjecting the element to differing mechanical loading, said method including the steps of:(g) comparing the admittance measured in step (e) with the admittance measured in step (d) to determine the relative magnitude of the measured admittances; and (h) determining from the relative magnitudes of the measured admittances, the direction of flow of the receiving gas. 28. The method of claim 27 wherein the admittance of the element and the frequency of the applied alternating electrical energization exhibit a linear relationship over a given range of alternating electrical energization frequencies and wherein step (b) is further defined as applying alternating electrical energization to the element at a frequency within the given range.29. The method of claim 1 further defined as altering the amplitude of the alternating electrical energization applied to the element.30. The method of claim 29 further defined as altering the amplitude of the alternating electrical energization applied to the element between a low level at which the pressure of the receiving gas is determined and a higher level at which discharge of the fluid substance occurs.31. The method of claim 22 further defined as including the steps of:establishing the amplitude of the alternating electrical energization applied to the element at a level below that at which atomization of the fluid substance occurs; determining the pressure of the breathing gases for the subject; when the pressure of the breathing gases bears a predetermined relationship to a preselected pressure level, increasing the amplitude of the alternating electrical energization applied to the element to a higher level at which discharge of the fluid substance into the breathing gases occurs; and thereafter reducing the amplitude of the alternating electrical energization applied to the element to the lower level. 32. The method of claim 29 further defined as including the step of removing electrical energy from the element for a period of time.33. A method for use with a discharging means discharging a fluid substance into a receiving gas, said method determining the flow direction of the receiving gas, said method comprising the steps of:(a) placing the discharging means in fluid communication with the receiving gas so that a bidirectional mechanical-electrical conversion element is subjected to mechanical loading responsive to the gas pressure of the receiving gas, the element mechanically vibrating responsive to the application of alternating electrical energization to the element, the element having an admittance, the admittance of the element at a given frequency of alternating electrical energization being alterable by a mechanical loading of the element, opposite directions of flow of the receiving gas subjecting the element to differing pressures and exerting differing mechanical loading on the element; (b) applying alternating electrical energization to the element at a selected frequency; (c) subjecting the element to mechanical loading responsive to the pressure of the receiving gas; (d) measuring the admittance exhibited by the element in the loaded condition when energized by the electrical energization of the selected frequency; (e) altering frequency of the alternating electrical energization applied to the element to a frequency higher or lower than that applied in step (b); (f) measuring the admittance exhibited by the element in the loaded condition when energized by the electrical energization of altered frequency; (g) using the relative magnitudes of the admittances measured in steps (d) and (f) and the direction of the frequency shift in alternating electrical energization to determine the nature of the mechanical loading on the element and the direction of flow of the receiving gas. 34. A method for use with a discharging means discharging a fluid substance into a receiving gas, said method determining the flow direction of the receiving gas, said method comprising the steps of:(a) placing the discharging means in fluid communication with the receiving gas so that a bidirectional mechanical-electrical conversion element is subjected to mechanical loading responsive to the gas pressure of the receiving gas, the element mechanically vibrating responsive to the application of alternating electrical energization to the element, the element having an admittance, the admittance of the element at a given frequency of alternating electrical energization being alterable by a mechanical loading of the element, opposite directions of flow of the receiving gas subjecting the element member to differing pressures and exerting differing mechanical loading on the element; (b) applying alternating electrical energization to the element at a selected frequency; (c) measuring the admittance exhibited by the element in an unloaded condition when energized by the electrical energization of the selected frequency; (d) subjecting the element to mechanical loading responsive to the pressure of the receiving gas; (e) measuring the admittance exhibited by the element in the loaded condition when energized by the electrical energization of the selected frequency; (f) comparing the admittance obtained in step (c) with the admittance obtained in step (e) to determine the relative magnitude of the measured admittances; and (g) determining from the relative magnitudes of the measured admittances, the direction of flow of the receiving gas. 35. The method of claim 34 wherein a pressure transducer comprising said element has a resonance frequency at which the admittance of the element has a peak value and wherein step (b) is further defined as applying alternating electrical energization to the element at a frequency other than the resonance frequency.36. Apparatus for discharging a fluid substance into a receiving gas, said apparatus determining the pressure of the receiving gas, and comprising:(a) fluid discharging means in fluid communication with the receiving gas, said discharging means having a bidirectional mechanical-electrical conversion element subjected to mechanical loading responsive to the gas pressure of the receiving gas, the element mechanically vibrating responsive to the application of alternating electrical energization to the element, the element having an admittance, the admittance of the element at a given frequency of alternating electrical energization being alterable by a mechanical loading of the element; (b) means for measuring the admittance exhibited by said element, the admittance exhibited by said element being measured at a selected frequency of alternating electrical energization when said element is subject to a mechanical loading; and (c) means for comparing the measured the admittance of said element when subjected to a mechanical loading with another value to provide an indication of the pressure of the receiving gas. 37. The apparatus of claim 36 wherein said admittance measuring means is further defined as measuring the admittance at a resonant frequency of a pressure transducer including said element.38. The apparatus of claim 36 wherein said admittance measuring means is further defined as measuring the admittance at a frequency other than the resonant frequency of a pressure transducer including said element.39. The apparatus of claim 36 wherein said admittance measuring means is further defined as also measuring the admittance of the element in the unloaded condition and wherein said comparing means is further defined as comparing the measured admittance of said element in the unloaded condition and the admittance of the element when subjected to mechanical loading.40. The apparatus of claim 36 wherein said comparing means is further defined as comparing the admittance of said element to a reference value.41. The apparatus of claim 40 further including means for deriving a value from a previously measured admittance of said element, wherein said comparing means determines a difference between said measured admittance value and said derived value and wherein said apparatus includes means for comparing the difference to a reference value as an indication of the pressure of the receiving gas.42. The apparatus of claim 36 further including a member subjected to the pressure of the receiving gas, said member being coupled to said element for mechanically loading said element.43. The apparatus of claim 42 wherein said member comprises a plate having perforations through which fluid is discharged into the receiving gas.44. The apparatus of claim 43 wherein said plate has a ring-like bidirectional mechanical-electrical conversion element coupled thereto and surrounding said perforations.45. The apparatus of claim 42 wherein said member comprises a piston reciprocating in a fluid filled housing for discharging fluid into the receiving gas.46. The apparatus of claim 36 wherein said element comprises a piezoelectric element.47. The apparatus of claim 36 wherein said element comprises a bi-morph structure.48. The apparatus of claim 36 wherein said admittance measuring means comprises means for applying alternating electrical energization having a desired voltage property which is constant in magnitude to the element; means for measuring the current through the element; and means for determining the admittance exhibited by the element from the voltage property and the measured current value.49. The apparatus of claim 36 wherein said admittance measuring means comprises means for applying alternating electrical energization having a desired current property which is constant in magnitude to the element; means for measuring the voltage across the element; and means for determining the admittance exhibited by the element from current property and the measured voltage.50. The apparatus of claim 36 wherein said admittance measuring means comprises means for measuring the phase shift in the alternating electrical energization as a result of its application to the element and means employing the phase shift to indicate the admittance of the element.51. The apparatus of claim 36 further defined as one for measuring the pressure of the breathing gases for a subject.52. The apparatus of claim 36 wherein the fluid discharging means comprises a nebulizer.53. The apparatus of claim 51 wherein the fluid discharging means comprises a nebulizer.54. The apparatus of claim 39 further defined as one for measuring a flow direction of the receiving gas, opposite directions of flow of the receiving gas subjecting the fluid discharging means element to differing pressures and subjecting the element to differing mechanical loading, and wherein said admittance measuring means is further defined as measuring the admittance exhibited by said element in the loaded condition at a frequency higher or lower than said selected frequency; and wherein said comparing means is further defined as employing the relative magnitudes of said measurements to determine the flow direction of the receiving gas.55. The apparatus of claim 37 further defined as one for measuring a flow direction of the receiving gas, opposite directions of flow of the receiving gas subjecting the fluid discharging means element to differing mechanical loading, wherein said pressure transducer has a resonance frequency at which the admittance of the elements has a peak value, the alternating electrical energization applied to said element being at a frequency other than the resonance frequency, and wherein said comparing means employs the relative magnitudes of said measurements to determine the flow direction of the receiving gas.56. Apparatus for discharging a fluid substance into a receiving gas, said apparatus determining the flow direction of the receiving gas, and comprising:(a) fluid discharging means in fluid communication with the receiving gas, said discharging means having a bidirectional mechanical-electrical conversion element subjected to mechanical loading responsive to the gas pressure of the receiving gas, the element mechanically vibrating responsive to the application of alternating electrical energization to the element, the element having an admittance, the admittance of the element at a given frequency of alternating electrical energization being alterable by a mechanical loading of the element; (b) means for measuring the admittance exhibited by said element, the admittance exhibited by said element being measured at a selected frequency of alternating electrical energization in the unloaded condition, said means measuring the admittance of said element at a frequency higher or lower than the selected frequency when said element is subjected to a mechanical loading; and (c) means for comparing the measured admittance of said element when said element is in the unloaded condition and the admittance of said element when said element is subjected to a mechanical loading to provide an indication of the flow direction of the receiving gas. 57. Apparatus for discharging a fluid substance into a receiving gas, said apparatus determining the flow direction of the receiving gas, and comprising:(a) fluid discharging means in fluid communication with the receiving gas, said discharging means having a bidirectional mechanical-electrical conversion element, a pressure transducer including said element having a resonance frequency at which the admittance of the element has a peak value, the element being subjected to a mechanical loading responsive to the gas pressure of the receiving gas, the element mechanically vibrating responsive to the application of alternating electrical energization to the element, the element having an admittance, the alternating electrical energization to the element being at a frequency other than the resonance frequency, the admittance of the element at a given frequency of alternating electrical energization being alterable by a mechanical loading of the element; (b) means for measuring the admittance exhibited by said element, the admittance exhibited by said element being measured in the unloaded condition and when said element is subjected to a mechanical loading on cud element; and (c) means for comparing the measured admittance of said element when said element is in the unloaded condition and the admittance of said element when said element is subjected to mechanical loading to provide an indication of the flow direction of the receiving gas. 58. A method for use with a discharging means discharging a fluid substance into a receiving gas, said method detecting the pressure of the receiving gas, said method comprising the steps of:(a) placing the discharging means in fluid communication with the receiving gas so that a bidirectional mechanical-electrical conversion element is subjected to a mechanical loading on said element responsive to the gas pressure of the receiving gas; (b) subjecting the element to mechanical loading responsive to the pressure of the receiving gas; and (c) measuring an electrical output of the element in the loaded condition. 59. The method of claim 58 wherein step (b) is further defined as subjecting a member to pressure exerted by the receiving gas, the member exerting mechanical loading on the element responsive to the gas pressure.60. The method of claim 59 wherein step (b) is further defined as subjecting a member comprising a porous plate, through which fluid is discharged into the receiving gas by a vibratory action of the element, to the pressure exerted by the receiving gas.61. The method of claim 59 wherein step (b) is further defined as subjecting a member comprising a piston that discharges fluid into the receiving gas by a vibratory action of the element to the pressure exerted by the receiving gas.62. The method of claim 58 wherein the bidirectional mechanical-electrical conversion element of the fluid discharging means comprises a piezoelectric element.63. The method of claim 62 wherein step (b) is further defined as exerting the mechanical loading on the piezoelectric element along an axis of vibration of the piezoelectric element.64. The method of claim 62 wherein step (b) is further defined as subjecting a member to pressure exerted by the receiving gas, the piezoelectric element is a ring-like piezoelectric element coupled to said member and wherein, in step (b), the pressure of the receiving gases applied to the member causes bowing of the member.65. The method of claim 59 wherein the bidirectional mechanical-electrical conversion element of the fluid discharging means comprises a bi-morph structure.66. The method of claim 62 wherein the piezoelectric element is a rod-like element for reciprocating a piston in a fluid filled housing.67. The method of claim 58 further defined as a method for measuring the pressure of the breathing gases for a subject.68. The method of claim 58 wherein the fluid discharging means comprises a nebulizer.69. The method of claim 67 wherein the fluid discharging means comprises a nebulizer.70. The method of claim 58 further defined as comparing the output of the element to a value for detecting the pressure of the receiving gas.71. The method of claim 70 further defined as comparing the output of the element to a reference value.72. The method of claim 70 further defined as comparing an output of the element to a value derived from a previously measured output of the element to determine a difference value and as further comparing the difference value to a reference value to detect the pressure of the receiving gas.73. Apparatus for discharging a fluid substance into a receiving gas, said apparatus detecting the pressure of the receiving gas, and comprising:(a) fluid discharging means in fluid communication with the receiving gas, said discharging means having a bidirectional mechanical-electrical conversion element subjected to a mechanical loading responsive to the gas pressure of the receiving gas; and (b) means for measuring an electrical output of said element to detect the pressure of the receiving gas. 74. The apparatus of claim 73 further including a member subjected to the pressure of the receiving gas, said member being coupled to said element for mechanically loading said element.75. The apparatus of claim 74 wherein said member comprises a plate having perforations through which fluid is discharged into the receiving gas.76. The apparatus of claim 75 wherein said plate has a ring-like bidirectional mechanical-electrical conversion element coupled thereto and surrounding said perforations.77. The apparatus of claim 74 wherein said member comprises a piston reciprocating in a fluid filled housing for discharging fluid into the receiving gas.78. The apparatus of claim 73 wherein said element comprises a piezoelectric element.79. The apparatus of claim 74 wherein said element comprises a bi-morph structure.80. The apparatus of claim 73 further defined as one for measuring the pressure of the breathing gases for a subject.81. The apparatus of claim 73 wherein the fluid discharging means comprises a nebulizer.82. The apparatus of claim 80 wherein the fluid discharging means comprises a nebulizer.83. The apparatus of claim 73 further including means for comparing the output of the element to a value to detect the pressure of the receiving gas.84. The apparatus of claim 83 further including means providing a reference value and wherein said comparing means is further defined as comparing the output of the element to said reference value.85. The apparatus of claim 83 further including means for deriving a value from a previously measured output of the element, wherein said comparing means determines a difference between said measured value and said derived value, and wherein said apparatus includes means for comparing the difference to a reference value to detect the pressure of the receiving gas.86. The method of claim 1, 13, or 58 further including the step of operating the discharging means in accordance with the receiving gas pressure indication.87. The apparatus of claim 36, 39, or 73 further defined as including means for operating said apparatus in accordance with the receiving gas pressure indication.