Bubble sensor: Difference between revisions
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⚫ | '''Bubble sensors''' are used to detect the presence of [[Liquid bubble|bubble]]s in [[Tube (fluid conveyance)|fluid-filled tube]]s. They play a vital role in many fields, including [[Health technology|medical technology]], [[process control]], [[Pharmaceutical industry|pharmaceutical]]s, and the [[petroleum industry]]. The most common type of sensors used are [[Ultrasonic transducer|ultrasonic]] or [[capacitor]] based. |
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[[File:Bubble Sensor.jpg|thumb|Bubble sensor for Extracorporeal Blood Circuits]] |
[[File:Bubble Sensor.jpg|thumb|Bubble sensor for Extracorporeal Blood Circuits]] |
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== Ultrasonic sensors == |
== Ultrasonic sensors == |
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Ultrasonic sensors |
Ultrasonic sensors use two techniques to detect bubbles, one method involves transmitting sound waves from a transducer through the fluid to a second transducer that detects the waves. A second method involves [[Pulse (signal processing)|pulse-echo]], sound waves are transmitted to the fluid, reflected and received by the same transmitter that sent it. In both of these methods bubbles will have an effect on the velocity, attenuation and the scattering of the sound, thus they are easily detected.<ref>W. N. Bostrom, D. D. Griffin, R. L. Kleinberg and K. K. Liang, "Ultrasonic bubble point sensor for petroleum fluids in remote and hostile environments," Measurement Science and Technology, vol. 16, pp. 2336-2343, 2005.</ref> |
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== Capacitive sensors == |
== Capacitive sensors == |
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Capacitive |
[[Capacitive sensor]]s due to their ease of fabrication and minimization capability have found uses in a number of industries, they can be efficiently designed on a [[printed circuit board]].<ref>T. V. Quoc, T. P. Quoc and T. C. Duc, "Capacitive Sensor Based on PCB Technology for Air," in IEEE SENSORS 2014 Proceedings. IEEE, 2014.</ref> A capacitor consist of two parallel electrodes with a capacitance computed as, |
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C =εA/d (1) |
C =εA/d (1) |
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Where ε is the permittivity of the dielectric medium, ''A'' is the cross sectional area of the electrodes and ''d'' is the distance between them |
Where ε is the permittivity of the [[dielectric]] medium, ''A'' is the cross sectional area of the electrodes and ''d'' is the distance between them. Liquids have a higher dielectric constant than gas; when an air bubble is in a fluid-filled tube the [[capacitance]] is reduced and the output voltage rises.<ref>N. P. Cheremisinof, Encyclopaedia of Fluid Mechanics: Volume 1 Flow Phenomena and Measurement, Houston, TX.</ref> The size of the bubble is inversely related to the measured capacitance. Table 1 shows a characteristics of capacitive sensor from research.<ref>M. G. A. Ahmed, A. B. Adam and J. O. Dennis, "Capacitor Device for Air Bubbles Monitoring," International Journal of Electrical & Computer IJECS, vol. 9, no. 10, pp. 12-15, 2009.</ref> |
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'''Table 1 Characteristics of Capacitive Sensors''' |
'''Table 1 Characteristics of Capacitive Sensors''' |
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== Uses in extracorporeal blood circuits == |
== Uses in extracorporeal blood circuits == |
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In various medical treatments that use Extracorporeal Blood Circuits (ECBC) the detection of air bubbles in the blood is vital for the patient safety. An air bubble in an artery that supplies blood to the heart or brain can cause serious injury or death. In an ECBC the bubble sensor is placed on the arterial pump that is supplying the blood to the heart. Depending on the size of the bubble detected the pump will respond in different ways. The sensors allow the operator to set a size threshold for the size of the bubbles to detect. If the bubbles are below the threshold it is displayed to the user as microbubble activity. When a bubble equal to or greater than the threshold is detected an audio and visual alarm is generated and the arterial pump is stopped, this effectively terminates the cardiopulmonary bypass. The operator must identify and remove the bubble before bypass can be re-instated.<ref>P. Kay and C. M. Munsch, Techniques in Extracorporeal Circulation, CRC Press, 2004. |
In various medical treatments that use [[Extracorporeal]] Blood Circuits (ECBC) the detection of air bubbles in the blood is vital for the patient safety.<ref>{{Cite journal|url=http://www.journal.uad.ac.id/index.php/TELKOMNIKA/article/view/884/683|title = Fault Tolerant Air Bubble Sensor using Triple Modular Redundancy Method|journal = Telkomnika (Telecommunication Computing Electronics and Control)|date = March 2013|volume = 11|issue = 1|pages = 71–78|last1 = Basjaruddin|first1 = Noor Cholis|last2 = Priyana|first2 = Yoga|last3 = Kuspriyanto|first3 = Kuspriyanto|doi = 10.12928/telkomnika.v11i1.884|doi-access = free}}</ref> An air bubble in an artery that supplies blood to the heart or brain can cause serious injury or death. In an ECBC the bubble sensor is placed on the arterial pump that is supplying the blood to the heart. Depending on the size of the bubble detected the pump will respond in different ways. The sensors allow the operator to set a size threshold for the size of the bubbles to detect. If the bubbles are below the threshold it is displayed to the user as microbubble activity. When a bubble equal to or greater than the threshold is detected an audio and visual alarm is generated and the arterial pump is stopped, this effectively terminates the [[cardiopulmonary bypass]]. The operator must identify and remove the bubble before bypass can be re-instated.<ref>P. Kay and C. M. Munsch, Techniques in Extracorporeal Circulation, CRC Press, 2004.</ref> |
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== References == |
== References == |
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{{reflist}} |
{{reflist}} |
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[[Category:Medical equipment]] |
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{{uncategorised|date=October 2015}} |
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[[Category:Sensors]] |
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[[Category:Bubbles (physics)]] |
Revision as of 18:41, 15 January 2024
Bubble sensors are used to detect the presence of bubbles in fluid-filled tubes. They play a vital role in many fields, including medical technology, process control, pharmaceuticals, and the petroleum industry. The most common type of sensors used are ultrasonic or capacitor based.
Ultrasonic sensors
Ultrasonic sensors use two techniques to detect bubbles, one method involves transmitting sound waves from a transducer through the fluid to a second transducer that detects the waves. A second method involves pulse-echo, sound waves are transmitted to the fluid, reflected and received by the same transmitter that sent it. In both of these methods bubbles will have an effect on the velocity, attenuation and the scattering of the sound, thus they are easily detected.[1]
Capacitive sensors
Capacitive sensors due to their ease of fabrication and minimization capability have found uses in a number of industries, they can be efficiently designed on a printed circuit board.[2] A capacitor consist of two parallel electrodes with a capacitance computed as,
C =εA/d (1)
Where ε is the permittivity of the dielectric medium, A is the cross sectional area of the electrodes and d is the distance between them. Liquids have a higher dielectric constant than gas; when an air bubble is in a fluid-filled tube the capacitance is reduced and the output voltage rises.[3] The size of the bubble is inversely related to the measured capacitance. Table 1 shows a characteristics of capacitive sensor from research.[4]
Capacitance (nF) | Air Bubble Diameter (mm) | Output Voltage (mV) |
---|---|---|
43.50 | 0 | 18.60 |
42.63 | 0.82 | 20.30 |
42.54 | 1.00 | 22.01 |
41.07 | 2.97 | 40.50 |
40.44 | 3.55 | 43.70 |
39.38 | 4.00 | 47.90 |
Table 1 Characteristics of Capacitive Sensors
Uses in extracorporeal blood circuits
In various medical treatments that use Extracorporeal Blood Circuits (ECBC) the detection of air bubbles in the blood is vital for the patient safety.[5] An air bubble in an artery that supplies blood to the heart or brain can cause serious injury or death. In an ECBC the bubble sensor is placed on the arterial pump that is supplying the blood to the heart. Depending on the size of the bubble detected the pump will respond in different ways. The sensors allow the operator to set a size threshold for the size of the bubbles to detect. If the bubbles are below the threshold it is displayed to the user as microbubble activity. When a bubble equal to or greater than the threshold is detected an audio and visual alarm is generated and the arterial pump is stopped, this effectively terminates the cardiopulmonary bypass. The operator must identify and remove the bubble before bypass can be re-instated.[6]
References
- ^ W. N. Bostrom, D. D. Griffin, R. L. Kleinberg and K. K. Liang, "Ultrasonic bubble point sensor for petroleum fluids in remote and hostile environments," Measurement Science and Technology, vol. 16, pp. 2336-2343, 2005.
- ^ T. V. Quoc, T. P. Quoc and T. C. Duc, "Capacitive Sensor Based on PCB Technology for Air," in IEEE SENSORS 2014 Proceedings. IEEE, 2014.
- ^ N. P. Cheremisinof, Encyclopaedia of Fluid Mechanics: Volume 1 Flow Phenomena and Measurement, Houston, TX.
- ^ M. G. A. Ahmed, A. B. Adam and J. O. Dennis, "Capacitor Device for Air Bubbles Monitoring," International Journal of Electrical & Computer IJECS, vol. 9, no. 10, pp. 12-15, 2009.
- ^ Basjaruddin, Noor Cholis; Priyana, Yoga; Kuspriyanto, Kuspriyanto (March 2013). "Fault Tolerant Air Bubble Sensor using Triple Modular Redundancy Method". Telkomnika (Telecommunication Computing Electronics and Control). 11 (1): 71–78. doi:10.12928/telkomnika.v11i1.884.
- ^ P. Kay and C. M. Munsch, Techniques in Extracorporeal Circulation, CRC Press, 2004.