Ultrasonic bubble sensors can achieve different accuracy by adjusting their settings. Here's some information about the effect of settings on accuracy:
Frequency setting: The frequency setting of the ultrasonic bubble sensor has a certain impact on its accuracy. In general, a higher frequency can provide greater accuracy because it can detect bubbles of small size more accurately. However, high frequencies can also cause the signal to be affected by noise and interference. Therefore, it is necessary to consider the application environment and requirements when setting the sensor frequency.
Sensitivity setting: Ultrasonic bubble sensors usually have a sensitivity adjustment function, which can be flexibly adjusted according to different application needs. By adjusting the sensitivity, you can control how sensitive the sensor is to detect air bubbles. Higher sensitivity can detect smaller bubbles, but it can also increase the likelihood of false positives. Conversely, lower sensitivity may reduce the accuracy of the sensor.
Data processing algorithms: Ultrasonic bubble sensors are usually equipped with some data processing algorithms for processing and analyzing the received echo signals. These algorithms can improve the accuracy and stability of the sensor. Sensor manufacturers often optimize algorithms based on application needs and provide corresponding parameterization options to meet different accuracy requirements.
Environmental factors: The accuracy of the sensor is also affected by environmental factors. For example, factors such as temperature, pressure, and the physical properties of the medium can have an impact on the performance and accuracy of the sensor. Therefore, when using ultrasonic bubble sensors, it is necessary to pay attention to environmental factors and set up and calibrate accordingly according to the actual situation.
The accuracy of the ultrasonic bubble sensor can be achieved by adjusting the frequency setting, sensitivity setting, data processing algorithm, and taking into account environmental factors. Depending on the specific application requirements, it can be set up to achieve the required level of accuracy.
Model example: AQ bubble sensor FCS16-25
AQ Bubble Sensor FCS10-25
AQ Bubble Sensor FCS16-50
AQ bubble sensor FCS22-50
AQ bubble sensor FCS35-50
AQ bubble sensor FCS46-64
The Swedish AQ bubble sensor FCS16-25 can detect 2mm bubbles