Oversizing inverters

Also if using PV Watts as a tool to get an estimate of production it should be noted that PV Watts assumes a 1.2 to 1 DC to AC ratio. Therefore if one wants to get a reasonable estimate of production they should calculate the DC to AC ratio and enter it into PV Watts along with other system parameters such as location, azimuth and tilt.

Definitely. I'm not saying it's not important. I'm just saying that starting out by saying "I want a 1.2 to 1 DC/AC ratio so I will . . . " doesn't generally give good results.

I agree with the concept that starting out with an idea of a randomly picked ratio can give bad results. . The ratio of 1.2 is the assumption in PVWatts and it is roughly what you get from a table from Enphase which matches micros to panels. I have noticed that when doing some scenerios that a ratio of 1.2 often gives the optimal resuts compared to lower or higher ratios depending on other factors. That ratio might be a good starting point unless there are good reasons to start with another number. It does have a probability of providing an optimal result, but other factors as you mentioned earlier may have more significance or influence on the initial design. One can enter other configurations to find an optimal mix if the data suggests.

That gets you the true max ROI. No one is doing this. So, rules of thumb?

- Use the largest panels possible that fit on your roof ....

- Minimize tilt. With my latitude (37.45°), 10 degree east/west tilt produced the most power, by far. I lose 16% efficiency vs optimum tilt, but with almost no inter row spacing, I gain about 30% in power with more panels.

- If you tilt, do it in a way that minimizes interrow spacing so you can get an extra row of panels in. Eg. Tilt 2 rows of panels in a single plane, instead of 2 planes, or optimally tilt only the most northerly row (in N. hemi), or tilt rows that have mandatory pathways or setbacks behind them

- don't use microinverters, use optimizers and hybrid or string inverters

- Everyone is using ROI in some way or another. Just that everyone's opinion of ROI acceptability differs depending on what they are trying to achieve.

Yeah, there might be some back and forth on choosing between max ROI and max payback, but most solar companies are not optimizing for either. They are pushing overpriced panels with undersized and overpriced inverters.

- I would say use the highest output panels available for the ideal physical size that maximises available roof space coverage

Again, the solar companies aren't optimizing for cost as well, which is a key component of maximizing ROI, so you end up with sub-optimal returns. If you are paying $1/watt for panels, you are overpaying and at least 3/4 of the bids I received included expensive panels.

- Tilt is subjective because it depends on how far north and south you are, how willing you are to clean the panels regularly. Low angled tilts attracts dust, bird poop and what nots so need more regular maintenance than steeper angles. I would say optimise the tilt depending on location and opportunity costs.

This is misleading. Optimizing for tilt angle does produce the max power from a panel, BUT it comes at a huge cost in lost roof space for more panels, especially for flat or low slope roofs. I just tried Toronto Canada on PVwatts, and the loss of 0 deg tilt vs 30-35deg tilt is less than 12% loss, but you'd gain 30-40%+ in roof space. That said, the higher the latitude, the less likely one has a low slope roof.

- Shadows from panel spacing of tilted panels is also an opportunity cost depending on where you are located and thus depending on time of day and length of time the shadows actually affect the panels behind. Microinverters, optimisers and half cut panels can often help to negate this.

If roof space doesn't constrain the number of panels you want to install, then inter row spacing is not much of an issue. But if you use an inter row spacing calculator, you can see how much roof space is needed for inter row spacing. The difference of space needed between 10 and 30 deg tilt is about 40% of the panel size (its actually 50%, but you also gain 10% roof because the area below the panel is 10% less with a 30deg tilt).

- the debate of micros vs op + string is never ending. I sit on the micro side because I have my own reasons and so will others. One cannot just say one is better than the other because it depends on the scenario that the system will be used in.

I was in the microinverter camp initially. But, I found out that IQ8A microinverters, the strongest ones by Enphase, top out at 386w output. If you are using anything over 400w panels, you are losing a substantial amount to clipping. Optimizers can handle up to 700w so you only have to worry about having a large enough string inverter. If you are only using 400w panels, then you are paying 10-15% more in racking, optimizers and installation costs. Not to mention microinverters are much more expensive per watt than optimizers + inverters by about 30-100% (eg. 25 400w panels with microinverters -about $200/panel- vs using 25 optimizers and a single 10k string inverter- about $100-120/panel).

I think the problem is the definition of "optimal results". Optimal results should be based on ROI, not on the output per panel or inverter. ......

There is a little piece of this conversation that is missing. In the case where the inverter maximum output is limited by either POCO rules or the electrical system in the facility, then oversizing the the panels is preferred since oversizing the inverter(s) is not possible. That allows the inverter(s) to run at maximum capacity for much longer time. ROI on the system is increased without a very expensive panel or POCO supply upgrade.

That is an important point that often drives the decision process and could lead to a high DC to AC ratio being chosen which may have a lot of clipping. If one were to e distracted by the clipping number one might not see the advantage of running the inverter at maximum capacity for longer.

I can't even see where it's needed in the design process.

Ampster: As several posters have observed in one way or another, a good design is usually a balance of design goals.
If one of those goals is to be able to have the lowest long term lowest cost of meeting the electrical needs of a dwelling (or at least < the long term cost of POCO power), that goal may be lost sight of if the cost penalties associated with undersizing an inverter or oversizing an array (or both) are not considered.
It's not about DC/AC ratios. It's about getting a good design that meets the design goals, one big one of which is usually cost effectiveness.

Ampster: As several posters have observed in one way or another, a good design is usually a balance of design goals.
.......

When you need to take into consideration high ambient temperatures and losses due to variables straying far from STC. Panels located in the sahara will definitely need to adjust the DC/AC ratio to consider the highest panel temperatures it could hit.

It seems to me there is too much discussion about optimizing a system or creating a "balance of design", when there are many shortcuts, or rules of thumb, that would dramatically lower upfront costs and would allow for the elimination of electricity payments. So far, I didn't get one bid (out of maybe 20) that was below $2/watt (many were over $3) and none of the bids actually provided 100% of electricity needs. Which means no solar companies are optimizing using cost as a variable to optimize. Frankly, I have a system with double to triple the power and costs less than the systems that were offered by solar companies.