Integration of Renewable Energy Systems (Technologies for Sustainable Life (TSL) – Concise Monograph Series)

Energy efficiency measures are generally less expensive than a renewable

energy (RE) system to provide the same amount of energy saved. The

Energy Information Administration reports that, on average, a dollar

spent on efficiency saves $2 off the cost of a renewable energy system

to provide the same amount of energy [IEA, 2011]. But as the saying

goes "you can't save yourself rich" and having installed sophisticated controls

and efficient systems, we need some source of energy to power

them. On-site renewable energy systems offer several advantages, especially

when operated in concert with a larger utility system. The main

reasons to consider RE is cost-effectiveness, but other reasons are as

diverse as: reduction of atmospheric emissions; compliance with regulations

requiring RE; enhanced reliability through redundant energy supply;

abate risks related to fuel availability and cost, or risk of fuel-spills

during delivery; score points in a sustainability rating; or as a mitigation

measure in a larger environmental-permitting process. Renewable

energy technologies used on buildings include daylighting; solar photovoltaics;

solar water heating; solar ventilation air preheating; passive

solar heating and cooling load avoidance; wind power; biomass heat (or

cogeneration as discussed in Chapter 8); anaerobic digestion of waste;

and geothermal heat. Ground source heat pumps are also often considered,

in-part, RE systems. Daylighting and the envelope measures

(passive heating and cooling) are often considered efficiency measures,

but daylighting is a direct and obvious use of solar energy in buildings,

and photovoltaics (PV), Solar Water Heating and Solar Ventilation

Air preheating are technologies to consider on any building project. We

even consider an example of hydroelectric power on the water supply to

a building.

We cover the operating principle of each type of system, list components

and provide schematic diagram of how components are assembled

into systems; provide information for cost estimate and life cycle cost

calculation, describe how system size may be optimized to minimize life

cycle cost, and we stress the importance of operations and maintenance

(O&M) over a long performance period. Significant emphasis is placed on

integration of RE into the conventional utility system, at both the

site level and from the perspective of the larger utility system, so that

savings due to the RE may be realized without compromising the reliability

of the system. Case studies are presented to exemplify application

of each technology.