Guided wave radar and you!

Level

Guided wave radar and you!



Here we are again to chat some more about radar! Today, the star of the article is the guided wave radar. Do you know when you should apply a guided wave radar rather than a non-contact radar? If you don’t, then keep reading! If you do, then keep reading anyway. You might see something new or find something to argue about with me.

So guided wave versus non-contact! If your process can take non-contact technology, you should consider going that route first. However, specific process conditions, such as low dielectric constants or high turbulence, can benefit from or even require guided wave radar.

I read an article written by a senior product manager who concluded by saying no perfect level measurement solution exists. That’s true. You have plenty of options on the market, and all the vendors will try to convince you they have the best solutions for your application.

The best choice for your application is the solution you can afford that  keeps your process running smoothly. But that’s another discussion. Let’s go deeper into the guided wave radar universe.

The principle of the matter

Guess what? Yep, the guided wave radar uses the time of flight principle! You can go back to our time of flight article if you need to brush up on the concept. We also have an article on frequency bands that you should read. You should understand these topics as they relate to level measurement and time of flight devices.

Back to this topic! A guided wave radar installs at the top of the tank, with the probe of the radar extending into the tank to make contact with the product. The device transmits a microwave signal down the probe to the product surface, which reflects the signal back. Then the transmitter can calculate that distance using the following formula:

Distance = (speed of light x time delay) / 2

So the radar measures the distance, but you want to know the level of the product, right? No worries. When you set up the transmitter, you include the minimum and maximum height of the application. Then the transmitter can calculate the level too! Good little gizmo!

Probe selection

Some probes have specific characteristics which can limit the guided wave radar, like length and mounting restrictions. You’ll also need to make sure the probe won’t come in contact with metallic objects or the walls of the tank. And if you have high turbulence, then you need to anchor the base of the sensor.

Guided wave radars generally use one of three types of probe – coaxial, twin element, and single element. Which will work best for you? Usually vendors provide tables or charts to help you select the right probe for your application, but let me give you a quick overview.

Courtesy of Smar

Coaxial probes cover a wide range of applications, including those with low dielectric constants in their products. For a long measurement range, the twin element probe is a good choice, and you can get a flexible or rigid one. In sticky or viscous products, you should probably use the single element probe.

Interface measurement

One great application of the guided wave radar is for measuring the interface of two products, such as oil and water. Of course, for this application to work, you need a different dielectric constant in each product.

When the signal reaches the surface with the lower dielectric constant, a portion of the signal returns to the transmitter. When the signal reaches the product with the higher dielectric constant, more of the signal returns. If you set it up properly for these conditions, your transmitter can calculate the level of each product.

Courtesy of ISA

Guided wave radars on the market

You have plenty of options on the market, and each vendor has specific requirements to implement the device in your process. Most devices allow for high pressure and wide temperature ranges to fit more processes. But always remember that you must install the device correctly to get accurate readings.

Also remember maintenance. Because the transmitter comes in contact with the product, it can develop problems with coating, buildup, clogging, and more. However, if you keep an eye on the diagnostics from your guided wave radar, then you can avoid unscheduled downtime.

Conclusion

If non-contact technology won’t fit your process, then consider the guided wave radar. As always, you need to scale out and think in the long term, about stability and maintenance down the line. So study your data and choose carefully!

Emerson has a nice video for one of its wireless guided wave radar devices:


More guided wave radars:

Related tags: guided radar level level measurement Radar radar level measurement
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