Happy to hear that! Thanks a lot for your support!

Thank you so much! We truly appreciate your kind message and support

Great suggestion!

Thanks for the feedback and suggestion, Silvestre! I will go ahead and pass it on to our course developers.

Thank you so much! It's our pleasure.

You're more than welcome! Thank you for your support.

Great to hear that, Brian!

Thank you very much!

Glad to hear that!

Glad it helped!

@@realpars yes friend, I will stay this channel

Glad it helped! Thanks for your support

Thank you very much!

Our pleasure!

Great to hear that, Pavunu! Thanks for your support

Welcome

All realpars teams again welcome 👌👌👌👌👌👌👌💐💐💐💐

Glad it was helpful!

Happy learning!

Most welcome!

Thank you, Micheal!

Thanks for adding that, Joao!

Great suggestion! I will happily pass it on to our course developers for possible future video courses. Thanks again for sharing.

@@realpars Thank you. I would expect that it is a piece of circuitry to protect the smoothing capacitor for blowing out from initial rampup voltage spike? That is my assumption but i would like to know how it works from physics standpoint.

@@Flankymanga Yes, you are correct. The resistor(s) in the pre-charge circuit slow the rate of capacitor charging so that the capacitors are not overcharged when the motor first turns on.

Great to hear that, Alexandre!

Great to hear that! Best of luck at your new job!

Thank you for your comment! We have the following two courses on VFD, feel free to check those out over here: www.realpars.com/courses?*=vfd Happy learning!

Thank you!

Glad you enjoyed it!

Thanks for sharing your topic suggestion, I will happily add this to the list. Happy learning!

No, but dynamic braking and other similar features can be found on most full-featured VFD packages.

@@realpars thanks for the info...

Most welcome!

Thank you for your question! The IGBT handles this based on the parameters programmed into the software. You simply send a signal to the drive to adjust the speed, either faster or slower. The PWM controls the frequency of the generated waveform. By altering the waveform, the VFD can change the frequency of the output signal, thus controlling the speed of the connected motor. We offer courses on these topics at RealPars.com. You can sign up for free if you haven't already. Here is a link for you to review and learn more. www.digikey.com/en/maker/blogs/2023/what-is-a-variable-frequency-drive-and-how-does-it-work#:~:text=The%20VFD%20feeds%20this%20waveform%20into%20the%20connected,output%20signal%20and%20control%20the%20connected%20motor%E2%80%99s%20speed. Happy learning!

Great suggestion, Dan! Thank you for sharing and happy learning.

@@realpars - Btw...last week, my team spent 4 days and nights looking the reason why trip a plant room with 12-15 VFD. We got crazy . Thanks

Hi Nimbo, Thanks for your comment! Those are great questions, I will be happy to pass them along to our course developers as a topic suggestion for future video courses. Thanks again for sharing!

That is a great question! Although T3 is not drawn as such, T3 would typically be a three-phase current transfer, which is comprised of three interconnected single-phase transformers in a single housing, either using a single “3 phase core” or three individual toroidal cores.

You're welcome!

You're very welcome!

Hi Marlon, Thanks for your comment! We currently do not have any courses on Schneider PLC, but I will go ahead and pass this on to our course developers as a suggestion. Hopefully, this is something we can work on for future courses. Thanks for sharing and happy learning!

I too working with Schneider plc. In Indian market 70% occupancy is Schneider.

Glad to hear that, Harish!

Thanks again!

Hi there, Thank you for your question. To start, it's essential to ensure that your motor aligns with the specific power requirements in your local area. It's crucial to follow safe electrical connections in your region to prevent potential fire hazards and electrical problems. Adapting your motor to match the local voltage and power standards and acquiring a Variable Frequency Drive (VFD) for precise speed and current control is the safest approach. Your sales representative should assist you in sizing the appropriate VFD for your needs. Additionally, I recommend consulting a licensed electrician familiar with your area's regulations for the proper hookup. Wishing you a productive learning experience with RealPars.

Thanks for your topic suggestion!

You're welcome!

You're very welcome!

Thank you!

think low vold lightning or free electricity

lol volt I mean

Thank you @Mothyone for reaching out with your question. We’re sorry, but we couldn’t quite understand your question regarding our video. Could you please clarify so we can assist you further?

A VFD will typically maintain a constant V/f ratio in order to minimize eddy currents and hysteresis losses. Therefore, voltage changes as frequency changes. If you have a 525VAC motor operating at 50Hz, the V/f ratio is 10.5. So if a VFD is used to adjust the frequency to 20 Hz, to keep the same V/f ration, the voltage to the motor will be reduced to 210 VAC.

Thank you!

Happy learning!

Thanks a lot!

Hi Michael, Thank you for your question. To detect a potential ground fault without causing a circuit trip, it's crucial to check for an imbalance in the electrical connection with a Ground Fault Detection (GFD) device. Testing on a single-phase Variable Frequency Drive (VFD) is essential. For a three-phase VFD, it's advisable to select any two of the three phases, as most three-phase GFD systems will monitor all three phases. Happy learning!

Hi Kashif, Thanks for your comment! To answer your question, I am actually not sure about that as this is done by our graphic and animation department.

Realpars.com has two courses on PID control: learn.realpars.com/courses/how-to-configure-a-pid-controller-in-tia-portal and learn.realpars.com/courses/PID-Controller. PID control using a VFD as the final control element is essentially the same as using a control valve as the final control element. There are differences in the way VFDs behave as compared to control valves, so the tuning of the PID loop will be different. Some advanced VFDs have the capability to perform the PID control inside of the VFD electronics, which is a whole different topic. I prefer to not use that feature of a VFD unless you have a very steady application, such as an AHU fan in an HVAC system. I have noted your course suggestion and I will pass it along to our course development team. Thank you!

@@realpars thank you! Yes, using proportional valve for PID control looks quite simple and understandable in terms of connections, since this valve utilizes analog signal from AO module. To change rotation speed of the pump we need to change current frequency on VFD, that is different from valve. For professional PLC programmer it is easy task, I suppose, but for beginners like me it is not so obvious. I think, contolling pump flowrate by changing motor rotation speed is very useful task for many applications. Thank you again for the information. Your courses are the best!

Thank you for your inquiry; it's an excellent one! The suitability of this approach depends on your specific engineering and safety requirements, as well as compliance with local codes in your region. Typically, to optimize cost savings and considering your engineering needs, you aim for a current imbalance of no more than 2 out of 3 leads. In the event one current wire feed experiences a break or fault, the remaining 2 out of 3 will carry a higher current load. Consequently, the electronic circuitry will detect this imbalance and trigger a fault condition in the drive before significant damage can occur. However, it's worth noting that many modern drives now incorporate three Current Transformers (CTs) to monitor current loads more effectively. For further information and to expand your knowledge on this topic, you can refer to the following link: en.wikipedia.org/wiki/Current_transformer Happy learning from RealPars!

Thanks a lot@@realpars

Motors perform best when the Volts/Frequency ratio remains constant. A motor designed for 400 VAC and50 Hz has a V/Hz ratio of 400/50 = 8. As long as that ratio is maintained at other frequencies, the motor will run efficiently/. A good VFD will require the input of the motor characteristics as parameters and use those parameters to adjust the output to the motor based on the frequency chosen to run. Using a good inverter-duty-rated motor with a VFD will help insure the longest life possible from your motor.

Hi Mehmet, you can find part 1 of this course series over here kzbin.info/www/bejne/fpLco6yviL2SptE Happy learning!

Thank you for the topic suggestion, I will happily go ahead and share this with our course developers.