A larger capacity battery typically lasts longer for a given solar
application because lead-acid batteries do not like deep cycling
(discharging a large percentage of its capacity). Depending upon the
battery, a battery discharging only 30 percent of its capacity before
recharging will have approximately 1100 charge/discharge cycles. The
same battery discharging 50 percent of its capacity will have
approximately 500 charge/discharge cycles. Discharging 100 percent
leaves the battery with only 200 charge/discharge cycles.
Batteries degrade over time based on discharge/charge cycles and
environmental conditions. Always monitor the battery system to obtain
the best performance of the solar powered system.
Use this as a guide to the approximate state of charge and in
determining when to apply conservation measures.
Average Voltage Readings Relative to Battery
Change
State of Charge (%) Open Circuit Voltage
100 13.0 or higher
75 12.6
50 12.1
25 11.66
0 11.4 or less
Solar Panels
Banner solar panels come in two common sizes for the
DXM Controller: 5 Watt and 20 Watt. Both panels are designed to
work with the DXM Controller but provide different charging characteristics. Use the 5 watt panel for light duty operation
and use the 20 watt panel when you require greater charging capabilities.
Solar Panel Voltage Current Typical DXM Configurations
5 Watt 17 V 0.29 A DXM slave controller, ISM radio, I/O base board
20 Watt 21 V 1 A DXM Controller with ISM radio and Cellular modem
Photovoltaic panels are very sensitive to shading. Unlike solar thermal panels, PV solar panels cannot tolerate shading
from a branch of a leafless tree or small amounts of snow in the corners of the panel. Because all cells are connected in a
series string, the weakest cell will bring down the other cells' power level.
Good quality solar panels will not degrade much from year to year, typically less than 1 percent .
Solar Panel Mounting
To capture the maximum amount of solar radiation throughout the year, mount a fixed solar panel to optimize the sun's
energy throughout the year. For the northern hemisphere, face the panel true south. For the southern hemisphere, face
the panel true north. If you are using a compass to orientate the panels, compensate for the difference between true north
and magnetic north. Magnetic declination varies across the globe.
A solar panel's average tilt from horizontal is at an angle equal to the latitude of the site location. For optimum
performance, adjust the tilt by plus 15 degrees in the winter or minus 15 degrees in the summer. For a fixed panel with a
consistent power requirement throughout the year, adjust the tilt angle to optimize for the winter months: latitude plus 15
degrees. Although in the summer months the angle may not be the most efficient, there are more hours of solar energy
available.
For sites with snow in the winter months, the increased angle helps to shed snow. A solar panel covered in snow produces
little or no power.
5.1 Recommended Solar Configurations
These solar panel and battery combinations assume direct sunlight for two to three hours a day. Solar insolation maps
provide approximate sun energy for various locations. The depth of battery discharge is assumed to be 50 percent.
Solar panel and battery combinations for a DXM Controller system
Solar Panel Battery Capacity
3
Days of Autonomy DXM mA DXM Controller
5 watt 10 Ahr 10 days 25 mA DXM Slave Controller - ISM radio and I/O base board
20 watt 14 Ahr 10 days 30 mA DXM Controller with ISM radio
3
Battery capacity (amp hour) is standard amp rating taken for 20 hours. Battery capacity should be monitored for reliable system power and may
need to be increased for cold weather locations.
DXM100 Controller Instruction Manual
www.bannerengineering.com - Tel: 763.544.3164 23
To Next Page
Loading...
