Power (W): 190 Watts
Open Circuit Voltage (V): 36.00 Voc
Short Circuit Current (A): 7.42 Isc
Maximum Power Voltage (V): 28.60 Vmp
Maximum Power Current (A): 6.64 Imp
Now, here’s what these mean to you!
First off, the Open Circuit Voltage (Voc). This is the voltage you will see present at the solar panel’s output when it is exposed to full sun and is not loaded. While this is not really relevant to the panel’s power output, it should be taken into consideration for two reasons: First, you should ensure that any equipment connected to the panel (meters, charge controllers, etc) is capable of handling the full Voc of the solar panel or the string of solar panels connected. Otherwise, equipment damage may occur when the sun hits the panels and they’re not loaded down. Consult the documentation on your charge controller if in doubt. Also, for your safety, be sure that any overcurrent protection devices or disconnect switches are rated for Voc or higher! Upon unpacking and installing your panels, if you’re lucky enough to get full sunlight hitting them, check the open circuit voltage – it should be close to Voc. If it’s too low, the panel may have a problem or be miswired (check the junction box).
Short Circuit Current (Isc). This measurement is useful for testing the panels and determining the sizing of your wiring and controller. Set your multimeter to amps, and connect the leads across the solar panel’s output terminals. In full sun, you should get Isc. If you do, the panel is operating correctly. Any wiring to the solar panels, and the charge controller itself, must be capable of handling the Isc of the array. Do not expect to load the panel down to Isc in normal operation, as you will be getting almost no voltage and extremely reduced power. (See I-V curve below!)
Maximum power voltage (Vmp) and amperage (Imp). These levels are very important to consider in selecting panels and components for your solar energy system! In short, please keep the voltage as close to Vmp as possible. The reason for this is that the solar panel has a certain internal impedance, and you will only receive maximum power when the panel output voltage *under load* is allowed to remain near Vmp. If you load the panel down to a lower voltage, it will become severely inefficient.
If you are using the solar panel with a conventional charge controller to charge lead-acid batteries, the ideal Vmp will be near the absorption charge voltage for your batteries. If you are using an MPPT charge controller, Vmp should be anywhere within the controller’s MPPT tracking range. This may be an extremely wide range of voltage, allowing you a lot of flexibility in choosing panels!
To illustrate the importance of the Vmp point, see the above I-V curve and power curve for a solar panel. Note that the power curve tapers down towards zero as the voltage falls below Vmp, and abruptly falls off as the voltage approaches Voc. If you buy solar panels and operate them too far from Vmp, you might as well be throwing money down a hole.
If you have an MPPT charge controller, it will periodically sweep the array voltage to find Vmp, which actually varies a little with different sunlight levels. For the best possible power output under all conditions, use an MPPT controller. The only exception I should point out: if you are using HF radio equipment, the switchmode boost/buck converter inside an MPPT controller may cause excessive noise on the receiver. Consider using a simpler charge controller in this case. The Morningstar ProStar series charge controllers have an internal jumper (really, a 0 ohm resistor that you can cut) to disable their PWM charge control to reduce RF noise to minimum.
Don’t toss your system efficiency and money down the toilet – choose your solar panels wisely!