yep, like I explained in earlier post, a scheme to increase decel ramp when too much regen power is immenent. I believe what most folks call 'bus comp' is indeed just this. More descrip from powerflex manual::
This method takes advantage of the characteristic of the induction motor whereby frequencies greater
than zero (DC braking) can be applied to a spinning motor that provides more braking torque without
causing the drive to regenerate.
1. On Stop, the drive output decreases based on the motor speed, keeping the motor out of the regen
region. This is accomplished by lowering the output frequency below the motor speed where
regeneration does not occur. This causes excess energy to be lost in the motor.
2. The method uses a PI based bus regulator to regulate the bus voltage to a reference (for example
750V) by automatically decreasing output frequency at the proper rate.
3. When the frequency is decreased to a point where the motor no longer causes the bus voltage to
increase, the frequency is forced to zero. DC brake is used to complete the stop if the DC Braking
Time is non-zero, then the output is shut off.
4. Use of the current regulator ensures that over current trips don’t occur and enable an easily
adjustable and controllable level of braking torque.
5. Use of the bus voltage regulator results in a smooth, continuous control of the frequency and forces
the maximum allowable braking torque to be utilized at all times.
6. Important: For this feature to function properly the active Bus Reg Mode A or B must be set to
Adjust “Freq” and NOT be “Disabled”.
Just reconfirms this is simply a routine to change decel ramp to attempt preventing overvoltage fault.
Hitachi does same with their AVG parameter B0161:
DC Bus AVR (Automatic Voltage Regulation
This function is to achieve stable DC
bus voltage in case of deceleration. DC
bus voltage rises du e to regeneration
during deceleration. When this
function is activated ( B130=01 or 02),
inverter controls the deceleration time
so that the DC bus voltage not to go up
to the overvoltage trip level, and leads
to the trip-less operation during
deceleration.
Please note that the actual
deceleration time can be longer in this
case.
Now I accept there may be a few drives with a routine that attempts to maintain a constant output voltage on a v/hz drive at a constant speed if bus voltage changes. But it still seems a waste when a few percent voltage change will have such a small effect on the motor performance and this routine must by definition be limited in range of adjustment.
It also is of zero value in a true vector drive since we regulate current and let the voltage do anything it needs in the process.
I also question any drive trying to increase output voltage by increasing PWM freq beyond where it should be to put harmonics in the motor to attempt to raise the average vs. rms sine motor voltage in attempt to raise voltage at a given set speed: we spend a majority of our time in design and application of drives striving to reduce output harmonics, which do nothing but add unusable heat in the motor and thus reduce its capacity.
I have searched many drive manuals in addition to the ones I have used and am familiar with and have found no definitive description to anything such as referred to in the initial posts here. I am still not a believer in a magic 'dc bus comp' routine that does more.
