1% clipping too high?

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310 BLAZE IT

Senior Member
Location
NJ
often you have a higher overall system efficiency when you increase clipping because the inverter operates in a more efficient region of its efficiency curve. This does not always occur but is something to look for. Where interconnection costs are a considerable effort risk, and expense, it is often more economical to oversize the system such that there is 3-4 percent clipping.
 

gadfly56

Senior Member
Location
New Jersey
Occupation
Professional Engineer, Fire & Life Safety
It's a matter of economics and design constraints. It can be a complex problem to solve and sometimes the best solution involves some clipping. As you say, it's not your field, so without understanding the details of the equation it may be counterintuitive for you.

I would think that you'd want to compare the area under the clipped vs non-clipped curve. That will tell you the lost revenue, which you can compare to the cost of up-sizing the inverter.
 

ggunn

PE (Electrical), NABCEP certified
Location
Austin, TX, USA
Occupation
Electrical Engineer - Photovoltaic Systems
I would think that you'd want to compare the area under the clipped vs non-clipped curve. That will tell you the lost revenue, which you can compare to the cost of up-sizing the inverter.

Of course; it's what I meant by "run the numbers" in post #33.
 

jaggedben

Senior Member
Location
Northern California
Occupation
Solar and Energy Storage Installer
I would think that you'd want to compare the area under the clipped vs non-clipped curve. That will tell you the lost revenue, which you can compare to the cost of up-sizing the inverter.

Or compare the area lost to clipping to what is gained on the 'shoulders' by spending the same money on more PV modules, and see which is more. Just for example.
 

gadfly56

Senior Member
Location
New Jersey
Occupation
Professional Engineer, Fire & Life Safety
Of course; it's what I meant by "run the numbers" in post #33.

Yes, but measuring the area under the curves is the "how to". Without the "how to," just saying "measure it" isn't very helpful.
 

ggunn

PE (Electrical), NABCEP certified
Location
Austin, TX, USA
Occupation
Electrical Engineer - Photovoltaic Systems
Yes, but measuring the area under the curves is the "how to". Without the "how to," just saying "measure it" isn't very helpful.

Just saying "measure the area under the curve" isn't all that helpful, either; how do you do that? I would hazard a guess that most of us in here are smart enough to figure out a way to run the numbers. Duh. :D
 

RustyShackleford

Senior Member
Location
NC
Occupation
electrical engineer
Just saying "measure the area under the curve" isn't all that helpful, either; how do you do that?
Seem to be some newbies here - as am I, maybe just a wee bit further up the learning curve than one or two others here. So, if you don't know about the PVWatts calculator (https://pvwatts.nrel.gov/pvwatts.php) please do check into it. Among other things, it will tell you the DC and AC production for every hour of every day of the year. A little Excel-fu, and you've got the area under the curve.
 

ggunn

PE (Electrical), NABCEP certified
Location
Austin, TX, USA
Occupation
Electrical Engineer - Photovoltaic Systems
Seem to be some newbies here - as am I, maybe just a wee bit further up the learning curve than one or two others here. So, if you don't know about the PVWatts calculator (https://pvwatts.nrel.gov/pvwatts.php) please do check into it. Among other things, it will tell you the DC and AC production for every hour of every day of the year. A little Excel-fu, and you've got the area under the curve.

I was being just a bit facetious; sorry.
 
Indeed. I'm currently trying to decide between a 3.8kW and 5.0kW inverter (SMA SunnyBoy line because of "secure power supply") for a system that is panel-constrained to 4.86kW under STC conditions. No-brainer to pick the 5.0kW inverter, especially since it's only $70 more (out of $1000 or so) ? Maybe not. Look at the efficiency curve:



Once you get below 10% or so of maximum output, the efficiency is going to roll off quite a bit; and you're gonna take that hit more with the larger capacity inverter. That could hurt your production a fair amount if the panels are operating at a low output a good bit of the time.

Meanwhile, clipping using the 3.8kW model is not as bad as you'd think, because those panels are never going to actually generate 4.86kW of DC (because that's under un-realistic testing conditions).

I think the effect of running at lower efficiency with a larger inverter will be very small. Just for rough numbers, and assuming the efficiency curves for the two inverters are similar (don know if that is true). : Say for round numbers you are considering a 3KW and a 6KW inverter. Say you are running 300 watts which is 10% of the 3KW and 5% of the 6KW. That is 95% vs 91% respectively, or 285 vs 273 watts. I think output within that 300 watt range is a rather small portion of the overall energy portfolio. I would certainly make up for a little bit of clipping, but Im not sure any substantial amount.
 
Indeed. I'm currently trying to decide between a 3.8kW and 5.0kW inverter (SMA SunnyBoy line because of "secure power supply") for a system that is panel-constrained to 4.86kW under STC conditions. No-brainer to pick the 5.0kW inverter, especially since it's only $70 more (out of $1000 or so) ? Maybe not. Look at the efficiency curve:



Once you get below 10% or so of maximum output, the efficiency is going to roll off quite a bit; and you're gonna take that hit more with the larger capacity inverter. That could hurt your production a fair amount if the panels are operating at a low output a good bit of the time.

Meanwhile, clipping using the 3.8kW model is not as bad as you'd think, because those panels are never going to actually generate 4.86kW of DC (because that's under un-realistic testing conditions).

I think the effect of running at lower efficiency with a larger inverter will be very small. Just for rough numbers, and assuming the efficiency curves for the two inverters are similar (don know if that is true). : Say for round numbers you are considering a 3KW and a 6KW inverter. Say you are running 300 watts which is 10% of the 3KW and 5% of the 6KW. That is 95% vs 91% respectively, or 285 vs 273 watts. I think output within that 300 watt range is a rather small portion of the overall energy portfolio. I would certainly make up for a little bit of clipping, but Im not sure any substantial amount.
 

RustyShackleford

Senior Member
Location
NC
Occupation
electrical engineer
I think the effect of running at lower efficiency with a larger inverter will be very small.
I think you're right. I have been going nuts with the hourly output file from PVWatts, and tried to make my own computation of AC power, using the DC power number it gives, and a piecewise-linear approximation to the efficiency curve I posted above. And it does seem to make well under 1% of difference.
 
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