Why is my silicon rectifier failing in my half-wave rectifier setup?

Click For Summary
SUMMARY

The discussion centers on the failure of a silicon rectifier in a half-wave rectifier setup for a universal motor powered by 230V AC at 50Hz. The primary cause of the rectifier breakdown is identified as inductive spikes occurring when the switch is opened or closed, exacerbated by insufficient capacitance (0.3μF) to absorb these spikes. Recommendations include adding a reverse-biased diode across the motor to mitigate inductive kickback and considering the use of triac controllers for better motor power management. The current draw of the motor is noted to peak at 6A during startup, which may contribute to the rectifier's failure.

PREREQUISITES
  • Understanding of half-wave rectification and its application in universal motors
  • Knowledge of inductive kickback and its effects on rectifiers
  • Familiarity with oscilloscope usage for measuring ripple voltage
  • Basic electrical circuit design principles
NEXT STEPS
  • Research the implementation of reverse-biased diodes for inductive load protection
  • Learn about triac controllers for efficient motor power management
  • Study the effects of ripple voltage on rectifier performance
  • Investigate the specifications and ratings of silicon rectifiers for high-current applications
USEFUL FOR

Electrical engineers, hobbyists working with motor control circuits, and anyone troubleshooting rectifier failures in AC to DC conversion setups.

silver5453
Messages
7
Reaction score
0
hi there,

I'm currently facing a problem with the silicon rectifier,
http://www.alldatasheet.com/datasheet-pdf/pdf/35499/RECTRON/6A8.html

with the current setup which is at the attachment.

The source is a AC current of 230V 50Hz , while the cap is at 0.3μF.
The setup is to provide a half-wave rectification to the universal motor.
The problem is that sometimes the rectifier breakdown, but when does it breakdown.

sorry if it might be a simple question, I'm not good in electrical circuits
 

Attachments

  • s_r_pic.png
    s_r_pic.png
    2.8 KB · Views: 531
Engineering news on Phys.org
How much current does the motor draw?

Do you have an oscilloscope? Can you measure the peak to peak ripple when the switch is closed? If you do have an oscilloscope be very careful when making this measurement. You need to use a 1:1 isolation transformer between the oscilloscope and the outlet.

When does the diode blow? When you open the switch, when the motor has a heavy load or a light load?

When you open the switch, how long does it take for the motor to coast to a stop?
 
Last edited:
Which rectifier are you using - there is a range of voltage specs for that rectifier.

The univ motor is a DC motor and you are only giving it 1/2 of a waveform - my guess is the inductive Kick back from the motor when the diode goes into reveres bias.

Best way to check is add a diode across the motor, normally reverse biased (it will look like it is reverse polarity of the existing diode. )

Also - note per your diagram the "top" of the motor is negative polarity - nothing wrong with that just not conventional drawing method.
 
skeptic2 said:
How much current does the motor draw?

usually the RMs current is around 1Amp, while the initial peak is around 6Amp when the motor start up.

Do you have an oscilloscope? Can you measure the peak to peak ripple when the switch is closed? If you do have an oscilloscope be very careful when making this measurement. You need to use a 1:1 isolation transformer between the oscilloscope and the outlet.

i've obtain the current profile before, there seems to be spikes when the switch is closed and when the switch is open. (unsure why did the that happen)

When does the diode blow? When you open the switch, when the motor has a heavy load or a light load?

Usually the diode breakdown upon closing/opening the switch, unable to confirm which is the caused.

When you open the switch, how long does it take for the motor to coast to a stop?

as edited above
 
I was trying to determine by my questions whether the rectifier was being destroyed by over voltage or by over current.

The peak to peak ripple voltage would give an indication of how much current the diode is conducting. It only conducts during the time the slope of the ripple voltage is positive. That time could easily be 1/10 or less of the whole cycle time. That means if the motor is drawing 1 amp, during a whole 50 Hz cycle, during the time when the diode is conducting, it could easily be conducting 10 amps or more. Since the diode blows upon opening or closing of the switch, it probably is not blowing because of over current. Nevertheless, it never hurts to overrate the rectifiers.

Most likely the diode is blowing because of inductive spikes when the switch is opened and I agree with Windadct's analysis. The capacitor isn't nearly large enough to absorb the inductive kick so a reverse biased rectifier across the motor is the best solution.

Why do need to use a rectifier with a universal motor?
 
Last edited:
skeptic2 said:
I was trying to determine by my questions whether the rectifier was being destroyed by over voltage or by over current.

The peak to peak ripple voltage would give an indication of how much current the diode is conducting. It only conducts during the time the slope of the ripple voltage is positive. That time could easily be 1/10 or less of the whole cycle time. That means if the motor is drawing 1 amp, during a whole 50 Hz cycle, during the time when the diode is conducting, it could easily be conducting 10 amps or more. Since the diode blows upon opening or closing of the switch, it probably is not blowing because of over current. Nevertheless, it never hurts to overrate the rectifiers.

Most likely the diode is blowing because of inductive spikes when the switch is opened and I agree with Windadct's analysis. The capacitor isn't nearly large enough to absorb the inductive kick so a reverse biased rectifier across the motor is the best solution.

Why do need to use a rectifier with a universal motor?

from what i understand, you mean placing a diode like so (as included in the attachment)

regarding the question of the usage of a rectifier with a U.motor, its because the necessity to reduce the motor power output.
 

Attachments

  • Untitled.png
    Untitled.png
    549 bytes · Views: 425
Connect the diode like this.
 

Attachments

  • CropperCapture[1].jpg
    CropperCapture[1].jpg
    19.1 KB · Views: 411
I would add a small (68pF) high voltage (say, 1.5kV) capacitor across each diode. That's cheap insurance.
 
How big is that universal motor?

Be aware a vacuum cleaner motor might draw more current than your 6 amp rectifier can handle,,, starting current may be easily 5X running. Vacuum cleaner motors are the better part of 1 horsepower.
 
  • #10
This may be a reverse recovery issue.

If the switch closes during the peak of the AC waveform, but in the reverse biased direction, the diode will conduct, in the reverse direction, for some period of time before it snaps off abruptly. Large power diodes can have substantial reverse recover times. If significant current builds up in the motors inductance before the diode snaps off, you can get huge surge in reverse voltage across the diode.

Why do you want to use the motor on only half of the AC waveform?
 
Last edited:
  • #11
Silver, there are triac controllers that will allow you to control the power to the motor and even power it down without using the switch. This might be a better solution albeit more expensive.
 

Similar threads

3 phase rectifier with cap filter w/overheating wire.
  • · Replies 10 ·
Replies
10
Views
9K
Super capacitor for running DC motor
  • · Replies 2 ·
Replies
2
Views
5K
MHB Current Through A half-wave rectifier
  • · Replies 8 ·
Replies
8
Views
4K