Nominal power - watt peak Question ??

Re: Nominal power - watt peak Question ??

Two that I find easy to use:

http://rredc.nrel.gov/solar/calculators/pvwatts/version1/ (limited international sites)
http://solarelectricityhandbook.com/solar-irradiance.html (lots of international sites)

I will copy and paste a post for Off Grid sizing with minimal information that was really a Grid Tied sizing question (oh-well, now the post can be useful for somebody). Note I am answering the question for a 10kWatt peak load (and no other information) on how I would start sizing the system.

You have a 97.3 kWH per day average load calculated--That is huge for an off grid system. The system I have penciled out is around 20 kWH per day--You can re-do the math, or simply multiply by ~5x to get a ~100 kWH per day answer for your loads:

Conservation and optimizing your energy usage (both peak and average) is key to having any sort of "affordable" off grid power system.

Can you design a system that will run 10-15 kWatt peak average load... Sure. It will just cost as much as a house in many parts of the country.

And, there is a big difference between peak power, and average kWatt*Hours per day of loads. In general, if you design for your kWH per day loads, you will usually be able to manage your peak loads too (i.e., a system large enough to provide XX kWH per day will start/run most any specific combination of loads you "normally" run).

If you have unusual needs (high peak loads, and low average loads)--Then that may be an issue. But until you start with the basics (how many kWH per day do you want to run)--A single peak load number is usually not enough to really get started on designing your system other in the most basic of rules of thumbs...

For example, a 10 kWatt system will need a minimum of 1,000 AH @ 48 volt battery bank.

A 48 volt battery bank will need 5% to 13% (roughly) to be properly charged:

• 1,000 AH * 59 volts charging * 1/0.77 panel+controller eff * 0.05 rate of charge = 3,831 watt array minimum
• 1,000 AH * 59 volts charging * 1/0.77 panel+controller eff * 0.10 rate of charge = 7,662 watt array nominal
• 1,000 AH * 59 volts charging * 1/0.77 panel+controller eff * 0.13 rate of charge = 9,961 watt array "cost effective" maximum

Assuming you are full time off grid and use the "nominal" array. And live around Amman Jordan, using Solar Electricity Handbook link for fixed array 58 degrees from vertical:

Amman
Average Solar Insolation figures

Measured in kWh/m²/day onto a solar panel set at a 58° angle:
(For best year-round performance)

Jan
Feb
Mar
Apr
May
Jun


3.71
4.30
5.29
5.99
6.53
6.73


Jul
Aug
Sep
Oct
Nov
Dec


6.72
6.61
6.35
5.44
4.27
3.54



Say you get a minimum of 5 hours of sun per day on "sunny days" were you need the cooling:

• 7,662 Watt Array * 0.52 off grid system eff * 5 hours min sun = 19,921 WH = 19.9 kWH per day

A 1,000 AH @ 48 battery bank used for 2 days of storage and 50% maximum discharge will supply:

• 1,000 AH * 48 volts * 0.85 inverter eff * 1/2 days * 0.50 max discharge = 8,160 WH = 8.2 kWH of average daily storage

Making a "balanced" system design requires you to both size for your "peak loads" (minimum size battery bank and AC inverter) and your "average loads" (Watts*Hours per day--Again size of battery bank and solar array to replace energy used).

Does this help?

-Bill