Global water instrumentation – Xylem SIT65 SATELLITE INTERNET TELEMETRY User Manual

Global Water Instrumentation

11

Typically, a system is designed to make sufficient power available during the worst

times of the year. In these cases, solar panels should be oriented to gather the most

light when the sun is lowest in the sky. In areas with snow, they may even be

pointed lower to allow the snow to slide off. This reduces the efficiency but overall,

will probably produce more total current. Clouds can reduce the output current of a

panel by 90% or more, even a small cloud will reduce the output to almost nothing as

it goes by. Shade is a very big factor and clouds create shade, even if it seems very

bright out.

Solar systems designed to provide enough power in the winter will produce far too

much in the summer. The result is the battery will become overcharged, reducing

the capacity to hold stored energy. When the following winter arrives, the battery

may not provide enough storage capacity to keep the system operating as it was

designed. For this reason, a charge controller should always be used. This device

senses the battery voltage and adjusts the charging current to match the demand.

The charger is selected based on the amount of solar capacity that is connected to it.

High ambient temperatures may make it necessary to over-rate the charger.

Many other factors affect the ability of a battery to maintain a charge. A solar system

that is under-rated will cause the battery to make large voltage fluctuations. Typical

batteries used in these applications are the sealed lead acid type, which slowly lose

capacity when charged and discharged by large amounts over long periods of time.

The larger the typical voltage fluctuations are, the more the effect. If the battery is

allowed to become severely overcharged or discharged, the capacity can be

significantly reduced. Low ambient temperatures also reduce available power

capacity but this capacity returns when the temperatures rise again.

The solar power output and battery capacity are the key design features. When

simplified; the capacity of the batteries is chosen based on the amount of time the

system needs to be running in the absence of sunlight, while the size of the solar

panels is chosen for their ability to recharge the batteries at the end of that time with

whatever sunlight may be available. What the worst case scenario is depends on

the application, but designing the system for that possibility is the ultimate goal.

There are too many applications to make estimates of what is typical. The total

power drain depends on transmission interval and system configuration; while

recharging limitations depend mostly on the environment. Two things to consider

are that an extra solar panel is usually cheaper than lost data, and the cost of a fresh

replacement battery is much less when someone is already in the field.