Please explain why inrush is the wrong term? In the OP's intended grinding application peak power causing the SMPS to shutdown or go into overload is most likely at startup and the inrush current is exactly the correct term to discuss.
I already explained, but I try to rephrase and elaborate (I'm trying to help here):
Wikipedia defines inrush current as:
"Inrush current, input surge current, or switch-on surge is the maximal instantaneous input current drawn by an electrical device when first turned on"
But the need to limit motor current has nothing to do with the initial state alone. The exact same situation happens whenever there is an increase in mechanical load, and RPM drops near zero. Inrush limiting doesn't do anything in this case, yet the user expects either of the following:
1) Automatic safety shutdown, or more often:
2) Limited current (and hence torque) to a safe level, whatever it is depending on the case. Current limiting for limiting winding and brush heating (and prevent core saturation, because the extra current over saturation limit won't produce any more torque, but still takes more power in). Torque limiting for mechanical reasons.
3) Combination of the two. Torque limiting for some time, automatic cutoff if torque integral exceeds some value.
Any standard "in-rush" limiting circuit, such as a soft start voltage ramp, naturally fails miserably, because it's only acting on startup, not during operation. A proper always-active limiter, OTOH, limits the current in all cases,
including but not limited to startup.
The logic is simple:
1) Inrush limiter only handles one case
2) Generic limiter handles all the cases,
3) Almost always (
especially in a grinder), many cases exist in addition to startup.
So while it is correct to say that motors have inrush current, it's not very meaningful because adding an inrush limiter won't usually solve the problem.
You could
think that simple motor applications like a fan would only need inrush control. Yet, about 15-10 years ago, all BLDC fans started implementing an in-operation current limiting mode with hickup recovery. Because fans get gummed up with dust, and the torque and current increases over time.
Why such "nitpicking" on terminology? Because searching for "inrush limiting" gives a lot of results of circuits and concepts that don't solve the problem! (If it exists, at all. If it doesn't, inrush limiting isn't needed either.)
Phenomena where initial energy delivery is needed to get a system to a steady state, is called inrush. An example is charging the output capacitor in voltage supply. But this is not the case with battery charging, LED drive, or most motor drives, where current limiting is needed as a part of normal operation, not only as a special startup case. Term "inrush" is not properly used in any of these cases. These loads are all equivalent to a voltage source and a very small series resistor, typically insufficient to limit current properly.
In the OP's intended grinding application peak power ... is most likely at startup
No, it likely isn't. Depends on actual grinding process, but it's highly likely that the grinder is often turned on without much mechanical load. The peak current is the same, but decays quickly as the RPM ramps up.
During grinding, I can see that the user pressed the grinder down hard, which could create a much longer-lasting surge than during the startup condition. Same current, but more energy -> more problematic if not handled. It may stall for say, for a second before the user reacts - this is already way longer than no-load rampup (inertia charging).
But let's not derail this more. If you need more information on this, please open another thread to get more help. As said, I strongly suspect at that such low voltages, no current limiting is actually needed at all (neither inrush, nor during operation). And I don't often say this! Full stall current at such low voltage is unlikely to be high enough to cause damage to the motor, and the supply is likely big enough to handle full stall current, for indefinite time. This is easy to verify by measuring the current, and looking for excessive heating in the motor during extended stall.
The OP provided nearly no information on usage and yet you have waxed lyrical with no idea of the motors efficiency and if the 1000W is BS inflated PMPO style or working power or anything other than marketing wank. Your attempted 'specific maths' is therefore not much better than useless.
What the heck is your problem? I'm trying to advocate math and understanding, even with initial napkin approximations, instead of cargo cult engineering. By all means, substitute for more accurate numbers once you got them. Math and understanding is important in engineering. I think you are on a wrong forum.
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