HomeMy WebLinkAboutCalifornia Creek FeasibilityStudyCalifornia Creek Hydroelectric Project
Pre-feasibility Study
Girdwood, Alaska
June 2007
Prepared for the Municipality of Anchorage
Heritage Land Bank
Brian Yanity
1a. Summary
A. Description
A small hydroelectric plant, with a generation capacity of about 125 kilowatts (kW), appears to be
economically and environmentally feasible on California Creek in Girdwood. A power plant of this
size would be enough to provide electric power to about forty homes along lower Crow Creek
Road. The plant’s water intake would be just below the boundary of Chugach State Park, and the
penstock (pipe that carries the water from the intake to the powerhouse) would be buried along
either side of California Creek for a total distance of 1/3 mile (600 m). The penstock will terminate
downhill at a small powerhouse a about ¼ mile (400 m) upstream from Crow Creek Road, with a
Pelton water turbine driving an alternating current (AC) generator.
B. Conclusions
The California Creek site has a potential capacity of 125 kW, with an average annual
energy of about 750,000 kilowatt-hours (kWh).
Installation cost is estimated to range between $600,000 and $800,000, with the cost of
energy produced ranging between 6 and 8 cents/kWh.
Permits required include at least a stream discharge and water rights permit, and the cost
to acquire them could be $100,000 or more.
The electricity demand of the planned residential development near the project site would
be several times greater than what California Creek will be able to produce.
For the California Creek hydropower site, a high head (vertical drop) Pelton turbine
system is preferred.
The hydroelectric plant would be designed and operated as a run-of-river facility, as there
is no environmentally acceptable way of constructing a water-storage dam and reservoir
in California Creek Valley.
There would be a small additional cost to local homeowners using California Creek
hydroelectric power in addition to that used from the Chugach Electric Association (CEA)
power grid. The economic attractiveness of local hydropower is likely to increase in the
years ahead along with the cost of CEA power.
It is uncertain whether or not CEA would accept electric power generated by a
hydroelectric plant on California Creek into the utility’s distribution grid. However, the
power could be used as a local source supplemental to the power grid without CEA
buying any of the power, as long as local residents arrange to purchase the power
independently.
C. Recommendations
The Heritage Land Bank should proceed with a full hydroelectric feasibility study of
California Creek, involving preliminary engineering design and field studies of the site’s
hydrology, environmental/ecologic, and geotechnical issues.
Combine a California Creek hydroelectric project with ongoing studies being conducted
for the Heritage Land Bank’s residential development.
2
1b. Key Data
General data:
Installed Capacity 125 kW
Number of Units 1
Type of Turbine Pelton
Average Annual Energy 750,000 kWh
Design Flow 0.20 m3/sec
Gross Head 120 m
Design (Net) Head 110 m
Penstock Length ≈ 600 m
Penstock Diameter ≈ 0.35 m
Diversion Structure Height 2 m
Economic data:
Annual grid power displaced: 750,000 kWh
Project cost (hydro plant and electrical distribution): $600,000 to $800,000
Annual project cost (20-year financing period) $45,000 to $60,000
Expected cost per kWh of Electricity Generated: 6 cents/kWh to 8 cents/kWh
Figure 1: Map of two possible alternative layouts for a California Creek hydroelectric plant
3
1c. Introduction
The California Creek hydroelectric project area would be located in the “western uplands” of the
land parcel owned by the Municipality of Anchorage (MOA), which is designated by the Girdwood
Area Plan as ‘open-space’. Presumably, the vast majority of this project area will remain publicly
owned. The hydroelectric facility can be designed to be largely invisible to passers-by. Buried
electrical cable and penstock piping is slightly more expensive than above-ground installation, but
it is out of sight. No significant ecological impacts on fish and wildlife are expected, although a full
environmental study needs to be carried out before site construction is approved.
Figure 2: Location of California Creek hydroelectric project in the Crow Creek Road area (map
image taken from Crow Creek Neighborhood Land Use Plan study by Agnew::Beck Consulting
(2006). )
4
Figure 3: Typical layout for a small-scale, run-of-river hydroelectric plant
Examples of similar-sized hydroelectric projects in Alaska:
Power Plant Location Owner Installed
Capacity
Lutak near Haines Alaska Power and Telephone 250 kW
Ouzinkie near Kodiak City of Ouzinkie 125
San Juan Lake Evans Island San Juan Fishing and Packing Co. 105
McRoberts Creek near Palmer Polarconsult 100
Armstrong Keta Port Armstrong Armstrong Keta, Inc. 80
Burnett Inlet Hatchery Etolin Island Southern Southeast Regional Aquaculture Assn. 80
Dry Spruce Bay Kodiak Island Wards Cove Packing Co. 75
College Sitka Sheldon Jackson College 60
2. Energy Demand and Future Demand Trends
Power users have a demand that varies throughout the year. For Girdwood, peak demand is in
winter. The electric power generated by California Creek would mostly be used by residential
units, and perhaps a few small commercial buildings. The proposed hydroelectric plant will be
right next to the planned Heritage Land Bank (HLB) residential development areas of “North Fan”
and “South Fan”, as part of a larger plan for the Crow Creek Road area. According to the 2005
report on HLB’s 981 acres, 1000 residential units are planned, between 60 and 75% of which will
be occupied year-round. These planned residential units will consist of 650 single-family
residences, 270 multi-family units, and 80 additional units as part of a later ‘development reserve’.
A distribution grid intertie with Chugach Electric Association (CEA) is planned as part of the new
residential development on HLB land, and any power demand forecast should be done in
conjunction with CEA. Assuming each residential unit uses an average of 1 kW of power
continuously, 600 units would require 600 kW of power. This amount of power is several times
what a hydroelectric plant on California Creek would be capable of producing.
5
3. Water Demand
During the highest-demand months of winter, all of the flow may be directed into the hydro plant
intake if necessary. Downstream water temperature and silt effects (described in environmental
concerns section below) of this ‘total stream diversion’ need to be studied. The Anchorage Water
and Wastewater Utility (AWWU) is considering expanding water and sewer service to the lower
Crow Creek Road area. No water for this purpose would need to be diverted from California
Creek because AWWU’s existing Glacier Valley well system is expected to be sufficient for future
needs. In sum, it is unlikely that water from the project area of California Creek would be used for
residential water supply or sewage treatment.
4. Energy Supply Options (Alternatives to Hydropower)
Utilization of local Chugach Electric Association distribution line:
Use of planned and existing distribution lines owned by Chugach Electric Association (CEA) is
the ‘base case scenario’ or ‘no-action alternative’. Effective April 1, 2007, CEA’s residential
electricity rates were 12.7 cents/kWh, and are expected to increase in the years ahead with Cook
Inlet natural gas prices.
In the early 1980s, a small hydroelectric project was proposed for Bear Creek near Hope, on the
south shore of Turnagain Arm. Like Girdwood, the small community of Hope is located on the
CEA power grid. The proposed 150 kW plant was not recommended by a U.S. Army Corps of
Engineers study because of the site’s inability to produce dependable power year-round, and the
community chose to stay with CEA grid power. However, the winter flow of California Creek is
more favorable compared to that of Bear Creek
Onsite electrical generation powered by diesel or natural gas:
Even with a small hydroelectric plant on California Creek, residents of the area may want a back-
up generator on site in the event of a grid outage. While a diesel-powered electric generation
plant is much less expensive to install than a hydroelectric plant of equal capacity, the bulk of its
energy cost is fuel prices. A major drawback to diesel generators located in a residential area is
localized air pollution. Another possibility is a micro-turbine power plant or cogeneration (heat and
power combined) facility fired by natural gas. Although more expensive than a diesel generation
system, a gas cogeneration system is more energy efficient and emits less air pollution. Natural
gas service in Girdwood is provided by the ENSTAR Natural Gas Co., with a gas pipeline
connecting to Anchorage.
5. Hydropower Potential
Assuming an overall power plant efficiency of 53%, the California Creek site could have an
installed capacity of 125 kW. This figure is calculated assuming that the available gross head
(vertical drop) of the site is about 120 m, though with a net head (see below) of 110 m. The power
plant’s design flow is assumed to be 0.20 m3 (200 liters) per second, or about 7 cubic feet per
second. This estimated design flow is based on streamflow measurements conducted in
November and December 2004 at a site just upstream of where Crow Creek Road crosses
California Creek on a bridge.
The town of Girdwood averages about 80 inches (200 cm) of annual precipitation, the
majority of which is in the form of snowfall. In the California Creek watershed, melt water from two
glaciers is the initial source of the stream, but less of a contributor than snowmelt, rainfall, and
groundwater. Future trends of climate change could very likely increase rainfall during winter, and
thus boost stream flow during the time of peak demand.
6
Figure 4: View of the Northwest side of upper California Creek Valley
Figure 5: View of the Northeast side of upper California Creek Valley.
7
Figure 6: View of lower California Creek Valley, facing east, with Mount Alyeska behind.
The amount of power which can be generated varies greatly during different times of the year.
Based on observations and hydrology studies of similar streams in the Chugach region, California
Creek’s lowest flow period lasts about two months, from March into mid-April. During this period,
the hydroelectric plant will only be able to produce a fraction of its installed capacity, or may have
to be shut down completely to avoid ice problems during low flow. Power from the CEA grid
would then have to make up for the drop in hydropower output.
Plant factor: Matching of supply and demand
Because a plant on California Creek would be designed for run-of-river operation, the stream’s
power production potential is opposite of demand curve. This is because the time of year when
there is peak energy demand, winter, corresponds to relatively low flow. There are two important
‘factors’ for the output of an electric power plant:
• Plant factor = (energy used)/(energy available)
• Load factor = (average load/peak load)
The hydro plant design should aim for the highest possible plant factor (at least 0.6) for highest
return on capital invested, and a lower unit cost of energy. The load factor for the California Creek
site should be high, because the electricity demand of the planned residential area will far outstrip
the hydroelectric plant’s maximum capacity. The most significant operating constraint on
hydropower production is the March-April period of lowest streamflow, because the forebay and
intake must have a minimum head to operate. Minimum flow requirements may also be specified
for California Creek, depending upon ecological and visual impacts. Also, yearly inspection
outages each summer are common for Alaska hydroelectric plants, for this is when power
demand is lowest.
8
6. Hydroelectric Plant Design
a. Civil Works
Prediction of flood levels is important for design of the power plant ‘civil works’, because the
ultimate test of a hydroelectric plant’s durability is during times of exceptionally high stream flow.
In addition, a geotechnical/geology site study would be required for a comprehensive feasibility
study, as well as recommendations for protection from natural hazards (rock fall, flooding,
avalanches).
Figure 7: Possible intake area on California Creek, looking upstream.
Figure 8: Possible intake area on California Creek, looking downstream.
9
Weir:
A ‘weir’ is small and visually unobtrusive dam-like structure used to raise the water level and
ensure the intake is deep enough for design flow. For the California Creek site, a weir would have
a height about 6 feet (2 m). At least part of the weir structure could be made from natural rock
elements found in the streambed.
Forebay:
A forebay is a ‘silt basin’ that slows down the flow speed of the water entering the intake. Such a
silt basin is needed for California Creek, a stream with a high ‘bedload’ of glacial and other
eroded sediment. Much of this water-bourn sediment is composed of hard abrasive materials,
which can cause expensive damage to the turbine. Also, enough sediment may cause blockage
of the intake. The finest type of stream sediment, glacial flour, can easily pass through the silt
basin and be carried through the turbine. However, glacial flour generally causes less damage
than coarser particles of stream sediment. A sluice-type spillway, directed downstream back into
California Creek, can be used to periodically clean out the silt basin and handle overflow
conditions.
Intake:
The hydroelectric plant must extract water from California Creek in a reliable and controllable
way. The location of the intake structure (including the weir and forebay) would be close to the
boundary of Municipality of Anchorage land and the Chugach State Park, or as high up on the
valley slope as possible without entering the park. A typical intake structure consists of a ‘trash
rack’ made from metal bars.
Penstock:
The penstock will consist of a buried pipe, about 600 m (2000 feet) in length, which carries water
downhill from the intake to the powerhouse. The penstock pipe to carry the design flow of 0.20
m3/sec would have an inner-diameter of 14” (or 0.35 m). The penstock outer-diameter, or pipe
wall thickness, needs to increase further downhill, in order handle increasing water pressure.
Material choices for the penstock pipe include high-density polyethylene (HDPE) plastic for low
pressures, and steel for higher pressure. At 120 m of gross head (vertical drop), assuming a head
loss of 10 m due to friction, the net head would be 110 m. As part of a complete feasibility study,
much more detailed head loss calculations for the two different penstock alternative layouts (west
or east slope) for California Creek. The route of the buried penstock could easily serve as a hiking
trail. The plant could even serve as a ‘tourist attraction’ with an interpretive sign explaining the
project features to recreational users of the California Creek Valley.
Figure 9: Penstock under construction for 100 kW McRoberts Creek hydroelectric plant,
near Palmer (photo courtesy of Polarconsult Alaska, Inc.)
10
Figure 10: Typical ‘upper penstock’ terrain along the ridgeline just south of California Creek.
Tailrace:
The tailrace conduit carries water out of the powerhouse and back into California Creek, and
needs to be oriented downstream to prevent ‘backwash’ of floodwater, debris, and bed load from
reaching the powerhouse.
b. Powerhouse
For a run-of-river hydroelectric plant of this size, a 12’ x 18’ (4m x 6m) concrete building would
serve as the powerhouse. The location of the powerhouse would be close to the uphill edges of
the “North Fan” and “South Fan” areas of planned residential development, and needs to be
above flood stage along the streambed.
Figure 11: Small concrete powerhouse structure for 100 kW McRoberts Creek hydroelectric plant,
near Palmer (photo courtesy of Polarconsult Alaska, Inc.)
11
Figure 12: Possible location for powerhouse along California Creek
Turbine:
A single 125-kW Pelton turbine is the most practical type for the California Creek site, which has
a low amount of flow relative to its net head.
Figure 13: Pelton turbine unit (10 MW size) installed at Terror Lake hydroelectric plant, Kodiak
12
Generator:
Power generation on the scale of 100 kW and above is generally three-phase, 60-Hz alternating
current (ac) synchronous generator. Connected to the generator inside the powerhouse will be a
load controller, and additional protective and control equipment. An asynchronous (induction)
generator could also be used, which is generally less expensive than a synchronous generator of
equal capacity. An induction generator is more easily synchronized with a local distribution grid,
though must be self-excited (with capacitors) during a grid outage.
Figure 14: Turbine-generator set for 100-kW McRoberts Creek hydroelectric plant, near Palmer,
(photo courtesy of Polarconsult Alaska, Inc.)
c. Power Distribution
Single-phase power is generally the rule for supplying electricity to residences, and the
conversion of three-phase power from the generator into one-phase for distribution is a simple
process. However, three-phase power requires less copper in a transmission line to carry the
same amount of power, and larger electrical loads such as motors (rated over 5 kW) are usually
only three-phase machines. In a full feasibility study, the connection to Chugach Electric
Association (CEA)’s distribution line along lower Crow Creek Road needs to be carefully
examined. There is no precedent for CEA buying power from a small, independent hydroelectric
plant connected to its distribution system. Important issues of electrical safety and operational
control would need to be worked out as part of a power-purchase agreement.
d. Other Infrastructure
At present, only hiking trails exist along either possible penstock route, and the closest road is
Crow Creek Road. The trail on either side of the creek would have to be expanded so that heavy
equipment can be brought up to the intake area.
13
7. Cold Climate Considerations
Intake ice problems:
Ice is expected to be a minor problem at the intake compared to glacial silt and rocks, though still
needs to be accounted for in the design of the intake structure. Frazil ice is likely to occur in
California Creek during the winter. This type of ice consists of small particles which form in
turbulent or open water during exceptionally cold temperatures, particularly winter nights. Frazil
ice can stick to an intake trashrack, potentially blocking all flow into the power plant. Electrically-
heated intake trashrack bars help prevent ice from sticking take up to 10 kW of power
consumption for an installation size of California Creek. During winter ice conditions, this heating
could result in a net power loss of 10 to 20%, though this only would be turned on during frazil ice
‘supercooled’ conditions. Frazil and other types of ice may have to mechanically cleared from the
intake area during cold weather.
Low winter flow:
Power plant generation capacity will be defined for a maximum output during the months of
November, December, January, and February. Winter flow measurements are the most important
for design of the hydroelectric plant, for this is period when the plant’s ‘design flow’ must be
optimized. Future climate change is expected to increase winter flow for streams in the Chugach
Range, although it is uncertain by how much.
8. Environmental Concerns
The most significant environmental benefit of a local hydroelectric plant is that there is no air
pollution, in contrast to a diesel or natural gas-powered generator of equal size.
Existing environmental conditions:
The project site is almost entirely covered by open, mature needleleaf forest. Part of the site near
Crow Creek Road includes a small amount of mature broadleaf forest. Construction of the
hydroelectric plant would require the clearing of some trees along the penstock route.
Visual impacts:
During times of peak energy demand (December, January, February) the stream could be de-
watered along the reach of the power plant. However, during the peak recreation season of
summer, only a small fraction of stream’s flow will be diverted into the power plant. The power
plant’s intake structure and powerhouse are small enough to be easily shield by trees or
shrubbery from view of hikers on nearby trails. The penstock route, however, will be buried and
cold also serve as a public trail.
Fish requirements:
The Alaska Department of Fish and Game (ADF&G) has tagged California Creek as State
Anadromous Fish Stream No. 247-60-10250-2007. According to ADF&G studies, adult pink, king
and coho salmon are found in the upper stretch of California Creek (the project area) during the
summer and early fall. Spawning and rearing of anadromous fish have not been observed in the
project area, though do occur about one mile downstream. The time of year when fish are present
in California Creek also corresponds to a time of relatively high flow, so only a small proportion of
the total stream flow would need to be taken away from fish habitat along the length of the
project.
14
Wildlife habitat:
Black and brown bears, moose, lynx and a variety of birds and small mammals can be found in
the California Creek Valley. However, most of the valley is in Chugach State Park land, and
would be unaffected by a hydroelectric installation. However, any possible construction impacts
need to be carefully studied, as heavy equipment would be brought up along the penstock route
and the intake area.
9. Operations and Maintenance
At the outset, it would have to be decided who would own the hydroelectric plant. The owning-
entity could be the Municipality of Anchorage, a cooperative organization of local homeowners, or
some other type of organization or business. And although the power plant would be remotely
operated, a special management committee should be formed to determine the operations and
maintenance (O&M) management structure, capabilities and costs. This O&M committee must
also prepare operation schedules, the advance ordering of spare parts, and maintenance
procedures. Also necessary is the preparation of training procedures and detailed O&M manuals
and adequate documentation from equipment manufacturers. O&M must be considered during
the design and contracting phase, since the typical lifespan of a hydroelectric plant is 50 years or
more. In order to repay its large capital cost of installation, a hydro plant needs to run efficiently
and continuously throughout its design life. To this end, O&M training must begin before the plant
goes online. The project team must also assess the need for ‘institution building’ to support the
project over the long term. Below are listed some power plant operational issues that need to be
worked out:
• How will the project be financed, and what will be the electric accounting (billing)
structure?
• Who collects revenues from power users? Who keeps accounts and visits the
bank?
• Who should perform maintenance work?
• If the plant breaks down due to extreme weather, an accident, or an equipment
failure, who do you call in order to fix it? What would be in an ‘emergency
management plan’?
10. Economic Analysis
As described above, the economic difference with fossil fuel-powered generation is that
hydroelectric plants have higher capital costs of construction, but operate with no fuel costs.
Based on an assumed installation cost ranging from $4800 to $6400 per kW, a 125-kW
hydroelectric plant on California Creek would have an estimated construction cost of $600,000 to
$800,000. Out of this total amount, the combined cost of 2000 feet of penstock pipe (both HDPE
or steel) and intake structure could be up to $300,000, and the cost of turbine-generator set
between $200,000 to $300,000. Sources of financing for a small hydroelectric project worth
investigating include grants and subsidized loans from the state or federal government.
The annual power generated by the 125-kW plant, assuming a plant factor of 0.68, would
be 750,000 kWh. The annual cost of the power plant, including O&M costs and assuming a 20-
year financing period (based on financial of similar-sized hydroelectric plants) is estimated to be
between $45,000 and $60,000. Therefore, the expected cost per kWh of electricity generated
would range between 6 and 8 cents/kWh. The projected additional cost to local homeowners
using California Creek hydroelectric power (in addition to that used from the CEA power grid)
appears to be small. These cost estimates need to be investigated in greater detail as part of a
comprehensive feasibility study.
15
11. Required Permits
The estimated costs for acquiring the permits listed below are about $100,000, but could be
higher depending on the amount of field studies which need to be conducted. Contact information
is listed below each government/regulatory agency that needs to be consulted.
Municipality of Anchorage
• Owner of all land in the project area is the municipal government’s Heritage Land Bank.
Arrangements involving zoning and rights-of-way would be worked out with other
municipal departments.
• Girdwood Board of Supervisors (http://www.muni.org/gbos/ )
State of Alaska
Department of Environmental Conservation
Division of Water
Michelle Bonnet, Section Manager
410 Willoughby Ave., Suite 303
Juneau, AK 99801-1795
Phone: 907-465-5158
Fax: 907-465-5274
Email: Michelle_Bonnet@dec.state.ak.us
• Master Permit Application for stream discharge
• A Certificate of Reasonable Assurance (Water Quality Certification) 401 is required only if
a federal permit is needed, such as a discharge permit from the U.S. Army Corps of
Engineers (see below).
• The project may require a ‘consistency review’ for the Alaska Coastal Zone Management
Plan because the greater watershed of Glacier Valley, including the waters of California
Creek, drains directly into Turnagain Arm.
Department of Natural Resources
Division of Mining, Land & Water
Water Resources Section
550 West 7th Avenue, Suite 1020
Anchorage, AK 99501-3577
Phone: 907-269-8503
Fax: 907-269-8947
The Dept. of Natural Resources would likely require a Water Rights Permit on California Creek,
and also must approve any weir and civil works construction.
16
Department of Fish and Game
Division of Wildlife Conservation
333 Raspberry Road
Anchorage, AK 99518-1599
Phone: (907) 267-2257
California Creek is listed by the Dept. of Fish and Game as State Anadromous Fish Stream No.
247-60-10250-2007. Habitat protection could require specified minimum stream flows in
California Creek during certain parts of the year, as determined by qualified biologists.
Department of Transportation and Public Facilities
Central Region
4111 Aviation Avenue
Anchorage, AK 99519
Gordon C. Keith, P.E.
Central Region Director
Phone: (907) 269-0770
Email: Gordon_Keith@dot.state.ak.us
Planned road improvements along lower Crow Creek Road may affect the California Creek
project area.
Regulatory Commission of Alaska
701 West Eighth Avenue, Suite 300
Anchorage, AK 99501-3469
Phone: (907) 276-6222
Email: rca_mail@rca.state.ak.us
The RCA webpage on Water Power Development: www.state.ak.us/rca/Hydroelectric
Federal Jurisdiction
It is unlikely that a small hydroelectric project on California Creek would fall under the jurisdiction
of the United States government. The closest lands of the Chugach National Forest to the
California Creek hydroelectric site are about one mile upstream.
Federal Energy Regulatory Commission (FERC):
If necessary, the project would need to receive a FERC confirmation of no jurisdiction for a
hydroelectric plant of under 5000 kW of capacity that is not on federal land, or “…lands of the
United States” (Section 32 of the Federal Power Act).
U.S. Army Corps of Engineers (USACE):
The USACE-Alaska District would need to be consulted regarding Section 404 of the Clean
Water Act, which concerns the discharge of fill or other materials in wetlands. The closest
wetlands to the California Creek hydroelectric project site are about a half mile downstream.
Permitting webpage of USACE-Alaska District: http://www.poa.usace.army.mil/reg/
17
18
14. References
Agnew::Beck Consulting (2006). Crow Creek Neighborhood Land Use Plan, Prepared for
Heritage Land Bank
Harvey, Adam, A. Brown, P. Hettiarachi and A. Inversin (1993). Micro-Hydro Design Manual: A
guide to small-scale water power schemes. Intermediate Technology Publications, London.
Inversin, Allen (1986). Micro-Hydropower Sourcebook: A practical guide to design and
implementation in developing countries. NRECA International Foundation, Arlington, VA.
U.S. Army Corps of Engineers- Alaska District (1984). Hydropower Potential of Bear Creek for
Hope, Alaska.