Manual Book

Therefore, assuming 100% efficiency:

Power In = Power Out

Volts In * Amps In = Volts out * Amps out

Although MPPT controllers are not 100% efficient, they are very close at about 92-95% efficient.

Therefore, when the user has a solar system whose Vmp is greater than the battery bank

voltage, then that potential difference is proportional to the current boost. The voltage generated

at the solar module needs to be stepped down to a rate that could charge the battery in a stable

fashion by which the amperage is boosted accordingly to the drop. It is entirely possible to have

a solar module generate 8 amps going into the charge controller and likewise have the charge

controller send 10 amps to the battery bank. This is the essence of the MPPT charge controllers

and their advantage over traditional charge controllers. In traditional charge controllers, that

stepped down voltage amount is wasted because the controller algorithm can only dissipate it

as heat. The following demonstrates a graphical point regarding the output of MPPT technology.

Temperature is a huge enemy of solar modules. As the environmental temperature

increases, the operating voltage (Vmp

) is reduced and limits the power generation of the solar

module. Despite the effectiveness of MPPT technology, the charging algorithm will

possibly

not have much to work with and therefore there is an inevitable decrease in

performance.

In this scenario, it would be preferred to have modules with higher nominal

voltage, so that

despite the drop in performance of the panel, the battery is still receiving

a current boost

because of the proportional drop in module voltage.

Limiting Effectiveness

Maximum

Power Point

Traditional

Controller

Operating

Range

Maximum

Power Point

Current vs. Voltage (12V System) Output Power(12V System)

Typical Battery

Voltage Range

CURRENT

VOLTAGE

10 15 17

CURRENT

VOLTAGE

10 15 17