We use cookies to enhance your experience. By continuing to browse this site you agree to our use of cookies. More info.
“Is this information on the level?” is a commonly asked question, especially in gangster movies. However, the real import of this question is known especially to fluid engineers who needed to measure fluid levels, using floats and a site glass. Today, with advanced technological developments in the field of fluid level sensing, determining the fluid level is much easier.
A very brief introduction to several commonly available methods of evaluating a fluid level is offered below:
The fluid level within a tank may be found by assessing the head pressure first, and then using a sensor to convert this signal into an output which directly shows the level. One such type of sensor is based on pressure sensing technology, such as gages and differential pressure transducers. Their advantages include ease of use and installation, with the flexibility to be fitted on to various types of level measurements and other applications within tanks. Such sensors may be mounted on the tank itself or designed to be used as submersible sensors. The difficulty of using this technology arises in situations which demand working with dirty and clogging materials, which leads to the obstruction of small-bore lines and openings, or in corrosive liquids which will break down the sensor over time. Foam and splashing can affect the accuracy of level determination of a flush mounted sensor but not a submersible one, because the latter is within the medium and not at its surface. However, the medium density can affect the precision of the measurements.
A Bubbler system is another set up which uses compressed gas pumped through submerged tubing connected to a sensor, in order to measure the fluid level. Such systems are ideal when open channel run-off is to be measured. Another situation would be when the level of fluid in a tank or duct is to be determined but foam, surface turbulence, debris or steam makes surface level measurement impractical or impossible by standard hydrostatic sensing techniques.
Ultrasonic sensors for fluid level measurements are becoming popular because of their ability to overcome many obstacles to fluid level sensing by other means. They are typically mounted above the tank or process vessel, and transmit a series of ultrasound pulses directed at the surface of the fluid. The time required for each pulse to reach the surface, be reflected off it and return to the sensor, is measured. This is then automatically converted by calculation into the distance from the sensor to the surface, and this output is transmitted as a current loop. The advantage of an ultrasound sensor is its distance (typically several inches) from the surface, so that the media type does not make any difference to the final output. This makes this sensor type useful in sanitary processes where corrosive media must be measured.
However, sensor installation must be done with care because the angle of the ultrasound beam and its range must be so as to excluding other objects capable of reflecting sound, which would vitiate the readings. These false echoes must be avoided. Thus media which splash, foam, or even fog are not suitable for ultrasonic sensors, and a dusty environment is also contraindicated.
Radar can be used in the same way as ultrasonic sensors, but use microwave radiation of low frequency rather than ultrasound waves, to detect the liquid surface. It is especially suitable for processes which involve liquid levels within the food, pharmaceutical, or beverage industries. The radar waves are much less susceptible to error in environments which contain dust, fog or surfaces which foam, unlike ultrasonic sensors.
Capacitance sensors detect fluid levels based upon the differences in dielectric properties of air and the liquid medium, the level of which is being determined. The principle is simple: a capacitor is formed by the conductive liquid, the tank wall within which it is contained, and an insulated active electrode. The increase or decrease of the level of the conductive medium causes a corresponding linear variance in the dielectric property of this capacitor. If the medium is non-conductive, on the other hand, a non-insulated metallic rod or cable is used as the electrode.
Insulated concentric sensors have enabled accurate level measurements at various interfaces, even when the medium contains different levels of water, oil or foam. However, a sound understanding of how the tank materials work together and of its grounding for electrostatic safety standard compliance is important for safe and accurate operation, which means a high degree of technical skill is necessary.
In order to select the appropriate type of sensor for fluid level sensing, various criteria must be considered, such as:
A large variety of technologies have now become available to enable the level of almost any liquid to be determined with great precision. However, the cost range is also quite wide. Again, as when volatile fluids are to be handled, approvals must be obtained beforehand to ensure a hazard-free environment, as also in the case of sanitary applications. Thus a sensor must be studied carefully and in detail before selection, to ensure that it best fits the installation conditions and working environment.
Finally, a failsafe mechanism is always strongly recommended, rather than relying on one single piece of equipment to ensure safe fluid levels are maintained at all times. This is because using the wrong sensors or sensing system, or choosing low cost over high quality, may prove to be a very expensive mistake in the long run.
This information has been sourced, reviewed and adapted from materials provided by Viatran.
For more information on this source, please visit Viatran.
Please use one of the following formats to cite this article in your essay, paper or report:
Viatran. (2019, September 13). Fluid Level Measurement Techniques. AZoSensors. Retrieved on June 02, 2022 from https://www.azosensors.com/article.aspx?ArticleID=1097.
Viatran. "Fluid Level Measurement Techniques". AZoSensors. 02 June 2022. <https://www.azosensors.com/article.aspx?ArticleID=1097>.
Viatran. "Fluid Level Measurement Techniques". AZoSensors. https://www.azosensors.com/article.aspx?ArticleID=1097. (accessed June 02, 2022).
Viatran. 2019. Fluid Level Measurement Techniques. AZoSensors, viewed 02 June 2022, https://www.azosensors.com/article.aspx?ArticleID=1097.
Do you have a review, update or anything you would like to add to this article?
AZoSensors speaks with Yuhan Huang from the University of Technology Sydney about his research into the development of on-road remote sensing technology that can rapidly and accurately identify high-emitting vehicles.
We speak with Okan Atalar about new research that could one day allow simple cameras, such as those on smartphones, to see the world in 3D.
AZoSensors speaks with Niraj K. Jha from the Electrical and Computer Engineering faculty at Princeton University. This interview explores the research proposing a framework called CovidDeep. CovidDeep combines efficient deep neural networks with commercially available wearable medical sensors for pe
The MCT469-SF Washdown is a compatible on-line NIR Sensor designed for continuous moisture and constituent measurement. It is ideal for washdown conditions in the food industry.
The MX 256 is a new control unit, completely digital, aimed at making the detection and measurement of gases easier. It can also be used for the processing of any digital signal from digital sensors (OLCT 10N types), and more.
Columbia Models SI-702AI and SI-702AIHP are biaxial force balance inclinometers designed with an output circuit configuration made for use in 4–20 mA data transmission systems.
AZoSensors.com - An AZoNetwork Site
Owned and operated by AZoNetwork, © 2000-2022