The Power of Inverters

Should you decide to use your Solar Array to power your electronics and appliances, you are going to need an inverter.  An inverter simply takes the DC (Direct Current) power produced by your solar panels or battery bank and inverts it into AC (Alternating Current) power.  While this seems easy enough, there are items you need to be aware of when selecting an inverter.  Here is a short list for you:

1)      Inverters come in different output types.

The two most common types of inverters are Pure Sine Wave and Modified Sine Wave.  Pure Sine Wave inverters best emulate your existing Utility Grid.  In most cases, the power from a Pure Sine Wave inverter is cleaner than the Grid.  This type of inverter is best suited when sensitive electronics are going to be used.  A Modified Sine Wave Inverter does not produce as clean of power as a Pure Sine Wave inverter.  However, a Modified Sine Wave can be more economical when power is your sole focus.

2)      Inverters are rated by Power Output

You need to select an inverter with at least the same output wattage as your maximum wattage needs.  The inverter Wattage Output is the maximum power you can get from that inverter.  For example, a 2000W inverter will output up to 2,000 watts worth of power continuously.  If you need more power than the output wattage rating, you need to choose a bigger inverter.

3)      Input DC Voltage

 The Input DC Voltage of the inverter must match the output voltage of your battery bank.  If this is not the case, the inverter will never run properly and cause damage to the inverter or the battery bank.  If your battery bank is 24 volts DC, than your inverter must have a 24 volt DC input rating.

4)      Inverter verses Inverter/Charger

Even though your goal is to solely charge the battery bank using your solar array, you may need an inverter/charger.  This type of inverter will allow you to utilize Grid power to charge your battery bank when the solar array isn’t producing energy.

Planning your project will allow you to choose the right products to meet your needs.  

Deficit Cycling equals Dead Batteries

In the last article, we mentioned the term deficit cycling.  But what is deficit cycling?  And more important, how does it affect you and your solar array?

Deficit cycling refers to a situation where the consumption of the batteries stored energy exceeds the energy production of the solar module.  This will cause the batteries capacity to slowly drain down towards zero.  Once that happens, you have a dead battery on your hands.

Here is how it works.  When you first get your battery, it is boosted to full capacity.  Let’s say this battery capacity is 200Ah for this example.  At a 50% Depth of Discharge, your available battery capacity for use is 100Ah.  With that in mind, you go ahead and use 100Ah.  Now, lets assume your solar module can only replace 90Ah worth of energy in a day.  This leaves your battery at a 10% deficit for that day (based on Depth of Discharge only).  The next day, you use 100Ah of battery capacity.  Again, the solar module can only replace 90Ah.  At the end of the day, your battery is at a 20% deficit.  In two more cycles, your batteries will be at a full 40% deficit.  A few more beyond that and the battery will begin to drastically reduce in performance and reliability.

An easy way to think about deficit cycling is like your bank account.  If you withdraw more funds than you are putting in, eventually you will have a zero balance.  The problem with batteries is that a zero balance means you finished off the battery and will need a new one.

Technology doesn’t trump a quality design

It bothers me to see how often technology is used to counter a poor system design.  It just doesn't make any sense.  And often times, the technology isn't being used for its actual purpose.

A prime example of this is charge controllers.  A charge controller is a device that takes the input power from the solar module and regulates the output.   By doing this, a charge controller can provide the right type of energy required by your battery.  More advanced charge controllers can actually assist in the maintenance of the battery itself. 

So far so good!  However, the charge controller's efforts are really only as good as the overall system design.  The available energy of a system is not based on the battery capacity.  The true limiting factor in available energy is the solar module production.  The solar module is the fuel for the battery.  A charge controller cannot compensate for a lack of energy production.  You must properly pair your solar module production with your battery.  Otherwise, your result will be deficit cycling.  Or in simple terms, you have a battery that just won’t last.