Hydropower does not discharge pollutants
into the environment; however, it is not free from adverse
environmental effects. Considerable efforts have been made to reduce
environmental problems associated with hydropower operations.
Efforts to ensure the safety of dams and
the use of newly available computer technologies to optimize operations
have provided additional opportunities to improve the environment. Yet,
many unanswered questions remain about how best to maintain the
economic viability of hydropower in the face of increased demands to
protect fish and other environmental resources.
Hydropower research and development today is primarily being conducted in the following areas:
- Fish Passage, Behavior, and Response
- Turbine-Related Projects
- Monitoring Tool Development
- Hydrology
- Water Quality
- Dam Safety
- Operations & Maintenance
- Water Resources Management
Today, engineers want to make the most
of new and existing facilities to increase production and efficiency.
Existing hydropower concepts and approaches include:
- Uprating existing power plants
- Developing small plants (low-head hydropower)
- Peaking with hydropower
- Pumped storage
- Tying hydropower to other forms of energy
Uprating
The uprating of existing hydroelectric
generator and turbine units at power plants is one of the most
immediate, cost-effective, and environmentally acceptable means of
developing additional electric power.
Low-head Hydropower
A low-head dam is one with a water drop
of less than 65 feet and a generating capacity less than 15,000 kW.
Large, high-head dams can produce more power at lower costs than
low-head dams, but construction of large dams may be limited by lack of
suitable sites, by environmental considerations, or by economic
conditions. In contrast, there are many existing small dams and drops in
elevation along canals where small generating plants could be
installed. New low-head dams could be built to increase output as well.
The key to the usefulness of such units is their ability to generate
power near where it is needed, reducing the power inevitably lost during
transmission.
Peaking with Hydropower
Demands for power vary greatly during
the day and night. These demands vary considerably from season to
season, as well. For example, the highest peaks are usually found during
summer daylight hours when air conditioners are running. Nuclear and
fossil fuel plants are not efficient for producing power for the short
periods of increased demand during peak periods. Their operational
requirements and their long startup times make them more efficient for
meeting baseload needs.
Since hydroelectric generators can be
started or stopped almost instantly, hydropower is more responsive than
most other energy sources for meeting peak demands. Water can be stored
overnight in a reservoir until needed during the day, and then released
through turbines to generate power to help supply the peak load demand.
This mixing of power sources offers a utility company the flexibility to
operate steam plants most efficiently as base plants while meeting peak
needs with the help of hydropower. This technique can help ensure
reliable supplies and may help eliminate brownouts and blackouts caused
by partial or total power failures.
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