Radar Level Transmitters: Setup and Working Principle

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Radar level transmitters electronic devices that are used for fluid level measurement. As the name suggests, these level transmitters use radar technology for fluid level detection. These transmitters function on the basis of electromagnetic waves at a range of 10GHz under microwave X-band bandwidth. Due to non-contact level measurement, these level transmitters have found their place in industries like mining, boiler technologies, paper and pulp industries, etc. How do these transmitters work? Why they have gained prominence in various industries? This is a two-part blog answer everything that you would like to know about these transmitters.

Radar Level Transmitter Setup

Instead of directly jumping to the working principle of radar level transmitters, it is important to understand the set up first. Let us discuss the components and assembly setup of a radar level transmitter.

The setup of radar lever transmitters is not complex rather easy to understand. It only features three fundamental components, which are as discussed below.

Solid-state Oscillator:

A solid-state oscillator functions as an electromagnetic signal transmitter. The solid-state oscillator sends out electromagnetic waves in the direction of fluid surface in order to measure the depth or level of fluid without any physical contact.

A radar Antenna:

The radar antenna in this system works as a transducer between the empty space in the fluid container and the electromagnetic signal sources or receivers. The antenna receives the process signals and transfers them to the receiver.

Receiver and Signal Processor System:

The receiver is a hardware microprocessor that converts the received signal into a reading. The signal processor performs the computer data conversion to digital readings.

Along with these three fundamental setup components of the radar level transmitters, the setup wizard is offered with advanced systems. This setup wizard support acts as a software interface to the transmitter operation. It makes the remote operation possible.

The working of radar level transmitters is based on these three setup components.

Working Principle of Radar Level Transmitters

The working principle of radar fluid lever transmitters is a function of Time Domain Reflectometry (TDR). It is also known as the Time of Flight (TOF) radar measuring principle. However, the step-by-step description of the radar level detector&#;s working principle is as follows.

• Since these transmitters are used as level sensors itself, it can be said that the electromagnetic signals are sent from the sensor. The solid-state oscillator that is installed in radar level sensor setup oscillates electromagnetic waves to the fluid surface. The distance can be measured considering oscillator as a reference point and fluid surface as the destination.
• Once electromagnetic waves hit a fluid surface, the surface itself reflects a pulsating signal to the radar antenna. The antenna transmits the signal to the receiver. As the receiver collects the signal returning pulse reflection, the time taken for reflection is calculated.
• The time to level calculation is performed by the signal processor. Once the signal processor translates reflection time into distance traveled that is considered as the depth of the fluid according to Time Domain Reflectometry.

This is the overall working principle of radar level detector sensors but the factors like Dielectric Constant (DC) of the fluid impact on the working efficiency of the sensor. The pulse reflection is highly impacted by dialectic constant as high DC pulsates strong reflections where low DC fluid absorbs most signals.

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Everything you need to know about radar level transmitters

Radar level sensors are becoming the primary option for level measurement in many industries. But how do they work? Where can you apply them? And what about IIoT radar devices?

You have a radar level sensor at your plant, right? If not, then this article can fill you in on how radar technology can help you out. If so, you should read the article too, to find out how the technology has evolved and understand more about IIoT radar devices.

Level measurement can be tricky sometimes. If you don&#;t pick the right device and set it up correctly, you&#;ll wind up with a headache. Of course, when you choose the right technology and configure it properly, you&#;ll practically forget about it because it keeps your process running smoothly.

Radar tech brings tons of benefits and has replaced many technologies in nearly all applications. Its popularity has increased as its cost has dropped, providing precise level measurement for less.

Let&#;s learn more about the technology and see how IIoT radars have become the tipping point for level monitoring on the market.

How do you measure levels in tanks?

The market offers an extensive list of models that use different methods to provide level measurement. How do you know which will work best for your process? As always, it depends on your process characteristics and requirements.

So what kind of sensor? Pressure, hydrostatic, capacitive, ultrasonic, something else? You could use any of those, but radar also fits in many different applications in many different ways. Pair it with IIoT and you&#;ll have half your work done for you!

For now, let&#;s dive into more details on radar devices. Later, I hope to bring you more information regarding other technologies.

How does a radar level transmitter work?

Radar level transmitters typically use one of two working principles, time-of-flight (ToF) and frequency-modulated continuous wave (FMCW). Up next &#; an explanation of each!

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Time-of-flight

With this method, a radar device measures the distance from itself to the product surface by emitting radar pulses to reflect from the surface back to the device.

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Its antenna receives the signal and sends it to the electronics, where all the magic happens. The microprocessor identifies the echo and calculates the time it took for the signal to return.

The distance (D) to the surface is proportional to the time of flight (t) of the pulse from the radar. Here&#;s the formula the microprocessor uses:

D = c · t/2

Here, c represents the speed of light.

After the device finds the distance (D), it can calculate the level (L) based on the empty distance (E):

L = E-D

Super simple!

Frequency-modulated continuous wave (FMCW)

For this method, the radar sensor emits a high-frequency signal. This frequency increases over time and it creates what we call a frequency sweep or signal sweep. This signal will reflect from the product surface to be received by the antenna and transmitted to the electronics with a time delay (t).

The frequency received differs from the frequency emitted, and the difference (Δf) is proportional to the echo curve. It applies the Fourier transform into a spectrum, as shown here:

Frequency-modulated continuous wave (FMCW)

The device then finds the level by calculating the difference between the tank height and the distance measured. This method is a bit more complex than the ToF method, but you don&#;t have to worry about that because the device does all the math for you.

Which frequency band?

You need to understand frequency bands or ask for expert help to determine which bands may fit your application best. You can find non-contact level sensors on the market with four different bands. Most use 6 GHz, 10 GHz, or 26 GHz.

Today, new radar sensors have come to the market with 80 GHz. These bring a lot of benefits to a process installation, as they fit well in applications where traditional radar transmitters need more room for the beam angle.

So which is the best frequency band for you? Because it depends on many factors in your application, you need to either do a lot of research or give your process information to an expert. Doing it yourself is more thorough, but the expert is faster. Up to you what you want to do.

IIoT level monitoring?

Ever heard of IIoT radar sensors? IIoT radar transmitters, such as the Micropilot FWR30 from Endress+Hauser, are the newest type of compact level sensor on the market.

This device installs easily in small tanks and can move with them if necessary. You get this portability because the radar uses battery power and wireless communication. That means you can transport a tank anywhere that has internet access and still retrieve data constantly.

You can also track this device locally, set up min/max thresholds, and receive alerts if the data changes. And because it uses the 80-Ghz frequency, you can install it easily in small containers for more reliable measurements.

Cloud-based IIoT radars like the FWR30 let you set up the device with just a few simple steps. Then you can access all your data using your , laptop, or tablet. On top of that, services like Netilion Value have excellent features such as a dashboard, history, map, notifications, and more.

When you&#;re ready to check things out, Netilion offers free trials. Other companies may as well, so do your research!

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Have a good one!

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