Various arrangements for determining whether a liquid is in contact with a nebulizer element are disclosed. A nebulizer element may be energized with an electrical signal at a measurement frequency. An impedance of the nebulizer element may be measured, thereby obtaining a measured impedance value.
Various arrangements for determining whether a liquid is in contact with a nebulizer element are disclosed. A nebulizer element may be energized with an electrical signal at a measurement frequency. An impedance of the nebulizer element may be measured, thereby obtaining a measured impedance value. The impedance value may be compared to a stored impedance value. Based on the comparison, it may be determined whether the liquid contacts the nebulizer element.
대표청구항▼
1. A method for determining whether a liquid is in contact with a nebulizer element, the method comprising: energizing the nebulizer element with an electrical signal at an atomization frequency;ceasing to energize the nebulizer element with the electrical signal at the atomization frequency;after c
1. A method for determining whether a liquid is in contact with a nebulizer element, the method comprising: energizing the nebulizer element with an electrical signal at an atomization frequency;ceasing to energize the nebulizer element with the electrical signal at the atomization frequency;after ceasing to energize the nebulizer element with the electrical signal at the atomization frequency, consecutively energizing the nebulizer element with the electrical signal at a plurality of measurement frequencies;measuring an impedance of the nebulizer element at each of the plurality of measurement frequencies, thereby obtaining a plurality of measured impedance value;calculating an average measured impedance value for the plurality of measured impedance values;comparing the average measured impedance value to a stored threshold impedance value; anddetermining whether the liquid contacts the nebulizer element using the comparison between the average measured impedance value and the stored threshold impedance value. 2. The method of claim 1, wherein each of the plurality of measurement frequencies is different from the atomization frequency at which the nebulizer is energized to atomize the liquid. 3. The method of claim 1, further comprising: if the nebulizer element is determined to not be in contact with liquid, ceasing to energize the nebulizer element with the electrical signal. 4. The method of claim 1, further comprising: if the nebulizer element is determined to be in contact with the liquid, energizing the nebulizer element with the electrical signal at an atomization frequency. 5. A system for energizing a nebulizer element when a liquid is in contact with the nebulizer element, the system comprising: a nebulizer, wherein the nebulizer comprises: a reservoir configured to store the liquid, wherein: the reservoir is configured to dispense the liquid to the nebulizer element; andthe nebulizer element, wherein: the nebulizer element is configured to, when energized by an electrical signal at an atomization frequency, atomize the liquid in contact with the nebulizer element; anda control module, wherein the control module is configured to: output the electrical signal at the atomization frequency to energize the nebulizer element;cease to output the electrical signal at the atomization frequency to energize the nebulizer element;after ceasing to output the electrical signal at the atomization frequency, consecutively output the electrical signal at a plurality of measurement frequencies to energize the nebulizer element;measure an impedance of the nebulizer element at each of the plurality of measurement frequencies, thereby obtaining a plurality of measured impedance values;calculate an average measured impedance value for the plurality of measured impedance values;compare the average measured impedance value to a stored impedance value; anddetermine whether the liquid contacts the nebulizer element using the comparison between the average measured impedance value and the stored impedance value. 6. The system of claim 5, wherein each of the plurality of measurement frequencies is different from the atomization frequency. 7. The system of claim 5, wherein, if the nebulizer element is determined by the control module to not be in contact with the liquid, the control module is configured to disable the nebulizer element such that the nebulizer element is not energized by the electrical signal at the atomization frequency. 8. The system of claim 5, wherein, if the nebulizer element is determined by the control module to be in contact with liquid, the control module is configured to re-energize the nebulizer element at the atomization frequency after ceasing to energize the nebulizer element with the electrical signal at the atomization frequency. 9. A non-transitory processor-readable medium comprising processor-readable instructions configured to cause a processor to: cause a nebulizer element to energize with an electrical signal at an atomization frequency;cause the nebulizer element to cease energizing with the electrical signal at the atomization frequency;after ceasing to energize the nebulizer element with the electrical signal at the atomization frequency, cause the nebulizer element to energize with the electrical signal at a plurality of measurement frequencies consecutively;cause an impedance of the nebulizer element to be measured at each of the plurality of measurement frequencies, thereby obtaining a plurality of measured impedance values;calculate an average measured impedance value for the plurality of measured impedance values;compare the average measured impedance value to a stored threshold impedance value; anddetermine whether the liquid contacts the nebulizer element using the comparison between the average measured impedance value and the stored threshold impedance value; and control energization of the nebulizer element based on determining whether the liquid contacts the nebulizer element. 10. The non-transitory processor-readable medium of claim 9, wherein the plurality of measurement frequencies are each different from the atomization frequency at which the nebulizer element is energized to atomize the liquid. 11. The non-transitory processor-readable medium of claim 9, wherein the processor-readable instructions that cause the processor to control energization of the nebulizer element based on determining whether the liquid contacts the nebulizer element comprise processor-readable instructions that, when executed, cause the processor to: if the nebulizer element is determined to not be in contact with liquid, cause the nebulizer element to cease being energized by the electrical signal at the atomization frequency. 12. The non-transitory processor-readable medium of claim 9, wherein the processor-readable instructions that cause the processor to control energization of the nebulizer element based on determining whether the liquid contacts the nebulizer element comprise processor-readable instructions that, when executed, cause the processor to: if the nebulizer element is determined to be in contact with liquid, cause the nebulizer element to be energized at the atomization frequency. 13. A method for determining whether a liquid is in contact with a nebulizer element, the method comprising: energizing the nebulizer element with an electrical signal at an atomization frequency;ceasing to energize the nebulizer element with the electrical signal at the atomization frequency;after ceasing to energize the nebulizer element with the electrical signal at the atomization frequency, consecutively energizing the nebulizer element with the electrical signal at a plurality of measurement frequencies;measuring an electrical characteristic at each of the plurality of measurement frequencies of the nebulizer element, thereby obtaining a plurality of measured electrical characteristic value;comparing the average measured electrical characteristic value to a stored threshold electrical characteristic value; anddetermining whether the liquid contacts the nebulizer element using the comparison between the average measured electrical characteristic value and the stored threshold electrical characteristic value.
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