Specifications
8
components, their configurations, or the specific interconnections to be used in the final
design. In the following sections, the different options and details about each option for
all major hardware components of the system will be discussed. Specific components
will not be selected here; this can be found in the design sections.
4.1.1 Batteries
Choosing the correct battery is one of the most critical parts of this design. Since there
is no guarantee that the sun will be out or that there will be wind at the time of the
blackouts, it is necessary for the power generated by the wind turbine and solar cells to
be stored in a battery as it is created, at the time these resources are available. In the
most extreme case, when the wind turbine and the solar cells aren‟t able to create any
power, the battery has to have enough energy stored to run a laptop and a projector for
at least two hours. Choosing a battery for this device may seem like an easy task at
first, but after closer consideration, it‟s a rather involved process. Since the goal is to
keep the entire unit as portable and modular as possible, the physical size and weight of
the battery must be limited. It‟s also important to consider the reliability, durability,
typical life span, ease of use, and the availability of the battery. There are many battery
types and sub-types that could be used for the intended application, a few of the most
viable of which will be discussed in detail below.
Lead acid batteries come in many forms. The most widely recognized form is known as
an SLI (starting, lighting, ignition) battery or a cranking battery. These are the typical 6V
and 12V automotive battery found in cars, motorcycles, and lawnmowers all over the
world. Cranking batteries can provide a high current for a short period of time and most
have a large enough storage capacity for our application. The problem is they are not
meant to be significantly discharged and re-charged, or deep cycled, very often. When
SLI batteries are subject to such deep cycle use, their life-span is quickly deteriorated.
The reason this occurs is cranking batteries are made with very thin and porous lead
plates, which maximizes the surface are in contact with the acid to in turn maximize the
instantaneous current they can provide. It is these thin lead plates that cause the battery
to fail quickly under repeated deep cycle operation, as the deep discharging and
recharging dissolves the lead. Once the lead plates are dissolved to a certain point, they
cannot be used. The lead plates are not replaceable, so the entire battery must be
replaced. Most of these batteries come in a form without caps to replace water that may
be lost, which causes a problem if the battery is overcharged multiple times. During
overcharging, the electrolyte inside the battery undergoes electrolysis, and the
hydrogen and oxygen gasses created can be released from the battery if the pressure
builds too high. If this occurs too many times, the water within the electrolyte can be
depleted, causing the lead plates to slowly lose contact with the electrolyte. These
batteries are usually designed with extra electrolyte already inside, which prolongs the
life of the battery in if overcharging does occur a few times, but it is limited. If the
electrolyte level on battery with removable caps gets low, the battery can be saved
simply by adding distilled water as often as necessary.
Another popular type of lead acid battery is known as a deep cycle battery, which are
also typically 6V or 12V. These batteries typically provide a more moderate current for a