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The ultrasonic flow measuring principle

For versatile and economical measurement of gases and liquids

Video Multiple industries 03.12.2024

Using ultrasonic waves, the flow volume of a wide variety of gases and liquids can be measured reliably – independent of electrical conductivity, pressure, temperature or viscosity.

Swimming against the flow requires more power and more time than swimming with the flow. This simple fact is the basis for ultrasonic flow measurement according to the “differential transit time” method: This method uses two sensors, set opposite each other in the measuring tube.

Each sensor can alternately transmit and receive ultrasonic signals while simultaneously measuring the signal transit time. As soon as the fluid in the tube starts to flow, the signals are accelerated in the direction of flow but delayed in the opposite direction. The differential transit time, measured by the two sensors, is directly proportional to the flow rate.

Watch the video to learn how the ultrasonic flow measuring principle works and read more about it here!

Advantages of ultrasonic flowmeters at a glance

  • Universal measuring principle for liquids and gases
  • Multivariable – simultaneous measuring of mass flow, density, temperature and viscosity
  • High measuring accuracy: typically: ±0.1% o.r., optionally: ±0.05% o.r. (PremiumCal)
  • Measuring principle independent of the physical fluid properties and the flow profile
  • No inlet/outlet runs necessary

Video Transcript

The most diverse substances are transported and distributed in piping systems every single day.
They can include solvents and chemicals, vegetable oils in the food sector, coolants in primary industry or petrochemical products.
The fluids flowing through pipes often have completely different properties. Therefore, different principles are required for their measurement.
One principle is flow measurement based on the differential transit time method using ultrasound.
The basic physics of this principle can be traced back to the English physicist and Nobel prize winner Lord Raleigh.
His book "Theory of Sound“ – published in 1877 – describes the propagation of sound waves in solids and gases.

Here is how this measurement method works:
Inside the ultrasonic flowmeter, sensor pairs are fitted across from each other in the measuring tube.
Each individual sensor can alternately transmit and receive an ultrasonic signal. Simultaneously, the transit times of these signals are measured.
The ultrasonic signals are generated with piezoelectrical crystals applying a voltage. Conversely, a piezoelectric crystal creates a voltage, when an ultrasonic signal impacts the sensor.
By increasing the number of sensor pairs it is possible to accurately detect and mathematically compensate for flow profile distortions over the entire pipe cross section.

During no flow condition, the signal transit times are the same – upstream and downstream.
Once the fluid starts to flow in the measuring tube, the ultrasonic signals are accelerated in the direction of flow and decelerated against the flow.
As a result, the ultrasonic signals now have different transit times – less time in the direction of flow and more time against the flow.
Therefore, the differential transit time measured by the sensors is directly proportional to the flow velocity in the pipe.
Together with the known tube cross-section, the actual flow volume can then be calculated.
The greater the flow velocity, the greater the measured time difference between the two ultrasonic signals.

For ultrasonic flow measurement, the sensors don’t necessarily have to be fitted into the pipe wall.
With a clamp-on design, for example, the sensors are fastened directly onto the outside of the pipe. This means they can be retrofitted at any time without interrupting the process.
With clamp-on sensors, the ultrasonic signal is passed directly through the pipe wall and into the fluid. The signal continues across the fluid, is reflected on the opposite pipe wall and then measured by the second sensor – in this example with a two-traverse installation.
Clamp-on design is unique because flow rates can be measured in very large pipes up to 4 meters in diameter. This increases the possible areas of application, for example in the water and hydroelectric industry.

Flexible mounting, process safety and cost-effectiveness are the distinctive advantages of ultrasonic flow measurement.
For all applications, we have the right solution.
Endress+Hauser – your single-source supplier for measurement technology!

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