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Trying to simulate an ultrasonic sonotrode

14 REPLIES 14
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Message 1 of 15
antolifauria
2605 Views, 14 Replies

Trying to simulate an ultrasonic sonotrode

Dear All,

 

My name is Antoli and I'm an engineering student from Spain. I'm involved in a project about ultrasounds in my university and I'm trying to simulate the ultrasonic equipment. This equipment is composed of a piezoelectric transducer (energy source), a booster and a sonotrode. The transducer has fixed frequency and fixed amplitude, and the booster and the sonotrode only amplify this amplitude. Both have to be tuned in the transducer frequency.

 

I know that simulate the piezoelectric transducer is very difficult, for this reason my idea would be to replace the transducer by its corresponding movement (amplitude: 20um, frequency: 20kHz) in order to get the amplitude at the end of the sonotrode.

 

I've done a simple natural frequency analysis but this isn't a correct approach for my application.

 

Could you give me some advice to simulate my equipment? Which would be the best way to success?

 

Thank you very much!

 

Antoli Fauria

14 REPLIES 14
Message 2 of 15

Antoli --

 

You can indeed do this by natural frequency (modal) analysis. If you know (or can determine) the gain of your booster Gb, then the input amplitude to the sonotrode Uinput is 20um*Gb. For the following example, assume Gb = 1.5 so Uinput = 30um.

 

With the above information you can run a modal analysis of the sonotrode alone. (Depending on your circumstance you may want to include the booster. However, this is usually not needed unless you are concerned with the booster's isolation mount or unless you don't  know the booster's gain.)

 

After you run the modal analysis, when you display the desired modeshape you will see the relative amplitudes. Rotate the model until you can see the center point where the booster would attach (generally the center of the sonotrode's input face). Right click on this node and then choose Inquire\Results. Record the displacement value in the direction of the booster's axis (i.e., in the direction of the input amplitude to the sonotrode). For example, if the booster's axis would be in the Z direction, then record DZ. This displacement is the reference displacement to which all others will be compared. For the following example, assume that this value is 13.6 (your value will be different).

 

Now you can compute the relative amplitudes at any other location on the sonotrode. For example, at the center of the sonotrode's output surface (the face) you may click and find a DZ value of 67.2. Then this location has a relative amplitude of 67.2/13.6 = 4.94. The actual amplitude will be 20um*1.5*4.94 = 148um (i.e., 20um transducer output * booster gain * sonotrode relative amplitude). If the sonotrode is symmetric then the transverse displacements at the center of the sonotrode's face will be small.

 

You can use this same method for any other location on the sonotrode. For example, at a corner you might have:

DZ = 58.3 ==> relative amplitude = 58.3/13.6 = 4.29 ==> 129 microns

DX = 4.7 ==> relative amplitude = 4.7/13.6 = .346 ==> 10.4 microns

DY = 5.2 ==> relative amplitude = 5.2/13.6 = .346 ==> 11.5 microns

 

You may want to make the following interface settings:

1. Set the "Results options" to "Absolute value". This will then typically display a dark color at the node(s) so that the node(s) can easily be located.

 

If you need the stresses then you will have to also run a frequency response analysis after the modal analysis.

 

Don Culp

www.krell-engineering.com

 

Message 3 of 15

Dear Don,

 

Thank you very much for your answer, it helps me a lot. However, I obtained a logical results without setting the "Results options" to "Absolute value", basically because I'm not able to find where can I set it.

 

Kind regards.

 

Antoli Fauria

Message 4 of 15

Antoli --

 

In the new ribbon interface click "Results Contours", then "Settings" dropdown list, then "Absolute value".

 

In the "classic/old" interface click on "Results options', then "Absolute value".

 

To change the interface:

- From the ribbon interface click "Tools", then "Application options",  then in the "General Information" tab "Ribbon style" will be checked. Click on this anyway and it will ask if you want to change to the Classic interface. Click Yes and "Cool look" will then be checked.

- From the Classic interface click "Tools", then "Options", then in the "General Information" tab click "Ribbon style".

 

Personally I like the Classic interface because it often needs fewer clicks.

 

Don Culp

 

Message 5 of 15

Don,

 

Thank you very much again. I am very grateful.

 

Kind regards.

 

Antolí

Message 6 of 15

Don,

 

I would be very grateful if you could help me with another small problem. I would like to force a sonotrode and a booster to vibrate at 20 kHz and then evaluate the amplitude. I think that with the natural frequency analysis type I can't do it. Which is the correct way to success?

 

Antolí

Message 7 of 15

Antoli --

Have you been able to extract the natural frequencies of the booster-sonotrode stack?

Do you want to know the amplitudes or do you also need the stresses?

Must the system vibrate at exactly 20000 Hz or will you be operating at one of the natural frequencies. (Unless you adjust your model very carefully, the primary natural frequency will probably not be at exactly 20000 Hz. For example, although your nominal frequency may be 20 kHz, you might find that your model tunes to 19912 Hz, which could be quite acceptable. Also, the performance of your manufactured stack will likely differ somewhat from the FEA results (e.g., slightly different material properties, effect of temperature during operation, effect of joints, etc.) In addition, the sharpness of the resonance for a typical stack means that operating only slightly away from the natural frequency will cause greatly reduced amplitude. This is why the power supplies (generators) are usually designed to track the frequency. Therefore, for FEA it is better to assume operation at the extracted primary natural frequency (assuming that it is reasonably close to the nominal) rather than at exactly 20000 Hz.)

If you can operate at the primary natural frequency then you can apply the same method as previously discussed. In this case, however, all amplitudes would be scaled relative to the amplitude input to the booster rather than the input amplitude to the sonotrode.

If you need to operate at exactly 20000 Hz, regardless of the primary natural frequency, then you must use Frequency Response Analysis. (I can explain this further if you need.)

Don Culp

Message 8 of 15

Don,

 

Absolutely. I was able to obtain the natural frequencies; your help was very useful. However, I observed that when you change the length of the sonotrode and run the natural frequencies mode, then you can't extract the performance of it at 20 kHz. So now, I would like to analyse what happen with the nodal planes and the amplitude if we fix the frequency (20 kHz).

 

For the moment I'm not interested in the stresses because the geometry of the booster and the sonotrode are very simply, and I think that I won't have any problem related to fractures when I manufacture and test them.

My ultrasonic generator works in a narrow range of 19,4 - 20,4 kHz, so if I don't do a correct simulation then the sonotrode and the booster will not vibrate. It could be really interesting for me if you were able to explain me the Frequency Response Analysis.

 

It's really interesting what you are explaining me.

 

Antolí

Message 9 of 15

Antoli --

 

Can you upload your current model without the results.  (In the classic interface: File\Archive\Create --> creates an archive .ach file.)

 

What version of FEMPRO are you using?

 

Don Culp

 

Message 10 of 15

Don,

 

You will find attached my model (booster + sonotrode).

 

I'm using the 2012 version.

 

Thank you.

 

Antolí

Message 11 of 15

Antoli --

 

I see that you have an axial resonance at 20509 Hz. I assume that this is the desired operating mode. What you should do is lengthen the sonotrode somewhat until the frequency is closer to 20000 Hz. If the sonotrode length must be fixed then you can remove material at a node to reduce the frequency. (I can provide details if needed.)

 

Notes:

 

1. When the sonotrode is manufactured you should allow extra material for final tuning. This is common for all sonotrodes, particularly to allow for material variations, especially for titanium.

2. If you want to reduce your meshing and run time then you could reduce your mesh density without significantly affecting the results. I prefer using "absolute mesh size" rather than "percent of automatic". Using a 4.0mm mesh reduced the run time by more than half while only increased the axial resonance by 4 Hz.

 

Don Culp

 

Message 12 of 15

Don,

 

The length of the sonotrode is not fixed. I told you that my generator works in a narrow range of frequency (between 19,4 and 20,4 kHz). Moreover I know that my piezoelectric transducer (alone) gives a frequency of 20,9 kHz. This means that the booster and the sonotrode must decrease the frequency of the equipment in order to set it in the range of the generator, isn't it?

 

The notes you wrote are very interesting, so I understand that in all cases I must allow extra material.

 

Antolí

Message 13 of 15

Antoli --

 

Yes, the sonotrode must be designed to compensate for any mis-tuning of the other components. However, the transducer may not be as mis-tuned as it appears. Acoustically, I consider that portion of the stud that protrudes into the transducer to be part of the transducer. (Similarly, I consider that portion of the stud that protrudes into the booster to be part of the booster.) With this assumption, the frequency of the transducer would be lower than bench-testing the transducer without a stud. You could check this by modeling the transducer without a stud and with a stud (with no stud protrusion beyond the transducer's face).

 

Yes, I would always recommend leaving extra material for tuning. If you are reasonably confident in your FEA material properties then you could adjust the pretune length in FEA to give a pretune frequency of ~19.5 kHz. This would leave 500 Hz for tuning in the machine shop. However, for the first sonotrode you might want to be more conservative and specify a pretune length that will give a pretune frequency of ~19.0 kHz. This would only require somewhat more material and tuning time. A tuned frequency specification of 20.0 kHz +/-100 Hz should be adequate.

 

Don Culp

 

Message 14 of 15

Don,

 

I believe you, so I'm not going to model the transducer. I think that it would be very difficult to reproduce the performance of the piezoelectric rings.

 

To sum up, I have to design the booster and the sonotrode assuming that the frequency of the equipment is 20 kHz (although we know that my transducer alone gives a frequency of 20,9 kHz). Then, in order to do the final tuning, I have to leave extra material at the end of the sonotrode. Do you agree?

 

Antolí

Message 15 of 15

Antoli --

 

Yes, I agree.

 

Don Culp

 

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