Alternative energy

Alternative energy

Alternative energy is energy provided from sources other than the three fossil fuels: coal, oil, and natural gas. Alternative sources of energy include nuclear power, solar power, wind power, water power, and geothermal energy, among others.

Current sources of energy

As of the beginning of the twenty-first century, fossil fuels (fuels formed over millions of years from the remains of plants and animals) provide more than 85 percent of the total energy used around the world. In the United States, two-thirds of the electricity is currently generated by burning fossil fuels like coal, gas, and oil. According to the U.S. Department of Energy and the Environmental Protection Agency, such combustion pumped almost 2.5 billion tons (2.3 billion metric tons) of carbon dioxide into the atmosphere in 1999. Over the last 150 years. some 270 billion tons (245 billion metric tons) of carbon in the form of carbon dioxide have been released into the air as a result of the burning of fossil fuels.

Words to Know

Active solar heating: A solar energy system that uses pumps or fans to circulate heat captured from the Sun.
Fossil fuel: A fuel such as coal, oil, or natural gas that is formed over millions of years from the remains of plants and animals.
Heat energy: The energy produced when two substances that have different temperatures are combined.
Passive solar heating: A solar energy system in which the heat of the Sun is captured, used, and stored by means of the design of a building and the materials from which it is made.
Photovoltaic cell: A device made of silicon that converts sunlight into electricity.
Radioactivity: The property possessed by some elements of spontaneously emitting energy in the form of particles or waves by disintegration of their atomic nuclei.
Solar collector: A device that absorbs sunlight and collects solar heat.
Turbine: An engine that turns in a circular motion when force, such as moving water, is applied to its parts.

Fossil fuels supply energy for transportation, industrial manufacturing, heating of buildings, and the production of electricity. However, the reserves of coal, oil, and natural gas are limited; in fact, they are called nonrenewable resources because once the supplies that are available are used up, they cannot be replaced. It is predicted that at the current rate of energy consumption, available reserves of oil and natural gas will be greatly decreased during the twenty-first century. Coal is more plentiful, but its use can contribute to environmental problems such as global warming (an increase in Earth's temperature over time). Because of growing energy demands in developing nations as well as the energy needs of industrialized societies, it will become increasingly necessary to turn to alternative sources of energy in the future. Conserving energy and using it more efficiently are additional ways of addressing the energy problem.

Nuclear power

Nuclear power is an alternative energy source that can be obtained from either the splitting of the nuclei of atoms (nuclear fission) or the combining of the nuclei of atoms (nuclear fusion). In either of these two reactions, great amounts of energy are released. Nuclear power plants use a device called a nuclear reactor in which uranium or plutonium atoms are split in controlled fission reactions. The heat energy released is captured and used to generate electricity. As of 2000, there were 110 operating nuclear power plants in the United States. France relies on nuclear power for more than 70 percent of its electricity production.
Controlled nuclear fusion is believed by many scientists to be the ultimate solution to the world's energy problems. The energy released in fusion reactions is many times greater than that released in fission reactions. To date, however, the technology has not been developed to make use of this source of energy.
Although nuclear power is a clean, cheap, and relatively safe means of providing energy, public concern over safety issues has brought the construction of new nuclear power plants to a virtual halt in the United States. The nuclear accidents at Three Mile Island in Pennsylvania in 1979 and at the Chernobyl nuclear power plant in Ukraine in 1986 (in which a large amount of radioactive material was released into the atmosphere) prompted fears of similar disasters occurring elsewhere. In addition, there is the problem of storing radioactive nuclear waste safely so that it does not pose a threat to humans or the environment.

Water power

The power of moving water, or hydropower, is a clean and efficient means of generating electricity. Water falling through dams powers water turbines that are hooked up with electric generators. The energy is then distributed across vast electrical networks. Canada, the United States, and Brazil lead the world in hydroelectricity production. The building of dams has an environmental impact, however, causing flooding of land above the dams and disrupting the normal flow of water below them, which can affect the natural ecosystem (a community of organisms and their environment) of a river.

Wind power

Wind power is one of the earliest forms of energy used by humankind. Windmills were used on farms in the early part of the twentieth century to pump water and generate electricity. Now considered an alternative energy source, wind power is being harnessed by modern windmills with lighter, stronger blades. In states such as California, New Hampshire, Oregon, and Montana, up to several hundred windmills may operate together (called wind farms) in open areas with steady winds. Single giant windmills capable of providing electricity to several thousand homes are also operating in the United States. Several power companies have plans to build large-scale wind farms in Texas, New Jersey, Massachusetts, and Minnesota, and smaller plants in Pennsylvania, Connecticut,

The wind power captured by these turbines at Tehachapi Pass, California, is a source of energy that does not harm the environment. (Reproduced by permission of the

U.S. Department of Energy

.)

and New York before 2020. By that year, the U.S. Department of Energy hopes the contribution of wind power to electrical generation nationwide will be increased by 5 percent. With new technologies being developed to improve windmill performance and efficiency, wind power is a promising, clean, cheap, and abundant source of energy for the future.

Solar power

Solar power, or energy from the Sun, is a free, abundant, and nonpolluting source of energy. Solar energy can be used to heat buildings and water and to produce electricity. However, the Sun does not always shine, and the process of collecting solar energy and storing it for use at night and on cloudy days is difficult and expensive.
Solar energy systems can be either passive or active. In a passive solar heating system, a building captures and stores the Sun's heat because of the way it is designed, the materials it is made of, or the heat-absorbing structures it possesses. An example of a passive system is a building with large windows facing south (that allow sunlight to enter) and with thick walls that store heat and release it at night.
Active solar energy systems use pumps or fans to circulate heat obtained by solar collectors. A solar collector is a device that absorbs the

A building sided with photo-voltaic cells, which capture the energy of the Sun and convert it into electrical energy. (Reproduced courtesy of the

Library of Congress

.)

energy of the Sun and converts it to heat for heating buildings and water. Flat-plate collectors are mounted to the roofs of buildings and used for space heating. They are made of a heat-absorbing plate, such as aluminum or copper, covered by glass or plastic. Water or air circulating in the collector absorbs heat from the plate and is carried to a heat storage tank. The stored heat is circulated or blown over cold rooms using pumps or fans. A conventional heating system is used as a backup when solar heat is not available. Solar heating of water is accomplished using a collector, a hot water storage tank, and a pump to circulate water.
Sunlight can be captured and converted into electric power using solar cells (called photovoltaic cells). Solar cells are usually made up of silicon and can convert light to electric current. They are used in space satellites to provide electricity, as well as in watches and pocket calculators. Solar panels made up of solar cells have been installed in some homes, and solar cells are used as energy sources in lighthouses, boats, and other remote locations.
Solar power plants—using energy from the Sun to produce steam for driving turbines to generate electricity—could potentially replace fuel-driven power plants, producing energy without any environmental hazards. In California, a solar power facility—using collectors made of large motorized mirrors that track the Sun—produces electricity to supplement the power needs of the Los Angeles utilities companies.

Geothermal energy

Geothermal energy is the natural heat generated in the interior of Earth and released from volcanoes and hot springs or from geysers that shoot out heated water and steam. Reservoirs of hot water and steam under Earth's surface can be accessed by drilling through the rock layer. The naturally heated water can be used to heat buildings, while the steam can be used to generate electricity. Steam can also be produced by pumping cold water into rock that is heated by geothermal energy; such steam is then used to produce electric power.
Geothermal energy is an important alternative energy source in areas of geothermal activity, including parts of the United States, Iceland, and Italy. Homes in Boise, Idaho, are heated using geothermal energy, as are most buildings in Iceland. The Geysers in California is the largest steam field in the world and has been used to produce electricity since 1960. Unlike solar energy and wind power, however, the use of geothermal energy has an environmental impact. Chemicals in the steam contribute to air pollution, and water mixed with the steam contains dissolved salts that can corrode pipes and harm aquatic ecosystems.

Tidal and ocean thermal energy

The rise and fall of ocean tides contain enormous amounts of energy that can be captured to produce electricity. In order for tidal power to be effective, however, the difference in height between low and high tides needs to be at least 20 feet (6 meters), and there are only a few places in the world where this occurs. A tidal station works like a hydropower dam, with its turbines spinning as the tide flows through them in the mouths of bays or estuaries (an arm of the sea at the lower end of a river), generating electricity. By the end of the twentieth century, tidal power plants were in operation in France, Russia, Canada, and China.
Ocean thermal energy uses the temperature change between the warmer surface waters and the colder depths to produce electrical power.

Biomass energy

Certain biomass (the sum total of living and dead plants, animals, and microorganisms in an area) can be used as fuel to produce heat energy. Wood, crops and crop waste, and wastes of plant, mineral, and animal matter are part of the biomass. The biomass contained in garbage can be burned to produce heat energy or can be allowed to decay and produce methane (natural gas). In western Europe, over 200 power plants burn rubbish to produce electricity. Methane can be converted to the liquid fuel methanol, and ethanol can be produced from fermentable crops such as sugar cane and sorghum. Adequate air pollution controls are necessary when biomass is burned to limit the release of carbon dioxide into the atmosphere.

Other sources of alternative energy

Other sources of alternative energy include hydrogen gas and fuel cells. Hydrogen gas is a potential source of fuel for automobiles, as well as a potential source of energy for heating buildings and generating electricity. Although hydrogen is not readily available, it can be produced by separating water into hydrogen and oxygen in a process called electrolysis. A disadvantage of using hydrogen gas as fuel is that it is highly flammable.
Fuel cells are devices that produce electric power from the interaction of hydrogen and oxygen gases. They are used to provide electricity in spacecraft and are a potential alternative energy source for heating buildings and powering automobiles.

Energy conservation

Energy conservation plays an extremely important role in reducing unnecessary energy consumption. Improving energy efficiency is the best way to meet energy demands without adding to air and water pollution. Designing gas-saving automobiles, using fluorescent lightbulbs, recycling, raising the setting for house air conditioners, improving the efficiency of appliances, and properly insulating buildings are some of the ways energy can be conserved.

Goals and objectives of the Renewable Energy

Goals and objectives of the Renewable Energy

 

1. To expand the use of renewable energy technologies in the United States and around the world.

2. To end America's dependence on unstable, unsustainable foreign sources of energy, and make the United States energy independent.

3. To lead and formulate public policy that promotes greater use of renewable energy.

4. To lead the research and development of new renewable energy technologies that lead to patents and the ability to license the renewable energy technologies we develop and invest.

5. To coordinate the research and development of renewable energy between universities so as to minimize redundancy and maximize results.

6. To facilitate and promote dialog between universities and professors in the free flow of research to enhance results and breakthroughs in renewable energy research and development. 

7. To educate and inform the public, including stakeholders that include residential, commercial, industrial and governmental organizations who are consumers of power and energy, the many benefits and uses of renewable energy.

8.  The Renewable Energy Institute will promote higher energy and electric power efficiencies and renewable energy technologies including; Anaerobic Digesters, Automated Demand Response, Biodiesel, Biomass Gasification, BioMethane and BioMethane Recovery, Cogeneration, Concentrating Solar Power, Demand Side Management, Dispersed Generation, Distributed Generation (onsite power generation), Fuel Cells, Geothermal, Hydrogen, Landfill Gas to Energy, Ocean and Tidal energy, Supply Side Management, Thermal Gasification, Trigeneration, Waste to Energy, Waste To Watts and to promote the use of energy crops and oilseed crops for producing biofuels and related technologies whenever a renewable fuel may be used in an internal combustion engine or gas turbine to produce clean power and energy. The Renewable Energy Institute will promote Carbon Dioxide Sequestration technologies, also called Carbon Capture and Sequestration.

9. To help farmers and growers in determining the optimum energy crops and oilseed crops they should consider for their specific locations, soils, climate and energy markets.

10. To adopt a goal of providing the U.S. with 50% of its' power and energy requirements from renewable energy sources by 2025, and 75% by 2050.  Texas will lead the way with a goal of 50% of its' power and energy requirements from renewable energy sources by 2020, and 75% by 2040.

11. To seek funding, investments and donations for the REI from concerned citizens, organizations and companies that will fund the REI's grants, research and development.

12. To seek and develop strategic partners/partnerships that share and advance our common goals. 

13. To seek out qualified companies and people that want to utilize our products and services under our license.

14. To provide Engineering Feasibility and Economic Analysis studies for customers - through a separate entity affiliated with the Renewable Energy Institute.

15. To develop renewable energy projects on behalf of customers - through a separate entity affiliated with the Renewable Energy Institute.

16. To remain committed as a trusted supplier of research, development and technologies and be committed as a "vendor-neutral" resource of information - until such time we identify "optimum" companies, products and/or technologies.

17. To promote and integrate the use of renewable energy technologies in creating "sustainable communities," "renewable energy districts," and "green buildings."  

18. To be committed to ending global warming, eliminating carbon dioxide emissions and greenhouse gas emissions from fossil fuels, and advance technologies such as carbon dioxide sequestration to end global climate change. 

Soaring oil prices and housing have helped to derail the economy

Soaring oil prices and housing have helped to derail the economy

Surge in crude has had an impact – less disposable funds for other goods

The silent killer of our economy

Many Americans are changing their spending habits. Cost of energy and other necessities have gone through the roof, leaving very little disposable funds for other goods.

The sub-prime mass and the lack of mortgage funds for housing are increasing our economic nosedive. The Feds can lower interest rate, if the financial institutions are not providing financing and or asking for a large down payment and a perfect credit score, the economy is not going no-where.

When the housing market is down, there is a snowball affect on other industries, appliances, furniture, carpeting, etc.

Economists will tell you that; when income is not keeping up with increases in the cost of housing there bound to be fallout.

Our automobile industry has gone to overseas companies, jobs lost forever. We must wake up and take some dramatic initiative to change this economic course.

Jobs in the United States are continuing to go overseas, our export has diminished substantially over the past 25 years and our imports have increased substantially in the same period.

We have resources, we have technology and manpower, why are we not utilizing them and devise a mechanism to re-instate our economic independence.

Put the politics and egos aside, let us all unite in a common cause, consider what is really good for our country without any hidden agenda or political favors. Bring honesty and integrity to our society; re-instate economic boom and fiscal responsibility.

We have been behind the eight ball before; we can muster whatever it takes to turn around our economic downturn.

Politicians are spending millions campaigning; those funds can be utilized for better purpose. Do not give me promises and tongue twisting, empty promises are easy “show me” that is the motto.

YJ Draiman

Alternative Energy System - My Home Photovoltaic (PV) Power System

My Home Photovoltaic (PV) Power System
Latest addition: A day in the life of my PV system
I've long been fascinated by electric power systems, especially ones that individuals can own and operate. During the annual Field Day ham radio contest that stresses independent sources of electric power, I always seemed to have more fun playing with the generators than actually operating the radios.
So when a friend and colleague, Mike Brock (WB6HHV), started a photovoltaic (PV) power system on his house, I got interested in doing one on mine. It helps that California has abundant sunlight and some of the most PV-friendly laws and regulations in the country. These include a net-metering law that requires the electric company to buy my surplus electricity at the full retail price, and a state-funded buy-down program that subsidizes part of the cost of such a "grid tied" PV system.
A "grid tied" PV system operates in conjunction with a conventional electric utility feed. If the PV system produces more power than needed to operate local loads, the excess is "sold" to the utility, running the electric meter backwards and generating a billing credit. When the local loads are greater than the power generated by the PV system, e.g., at night or when large loads are being operated, the meter runs forward.
PV technology is maturing rapidly, though the cost is still not low enough to compete directly with utility electric rates, even with the government subsidies. So I maintain no illusions that I'm doing this to save money. Nor am I one of those loony Y2K survivalists. I'm doing it because of a long-standing interest in the technology. I also get some side benefits, such as a UPS (uninterruptable power supply) that can run my computers for hours in the event of a power failure.
Solar Panels

Here you can see the twelve Astropower AP1206 solar panels on my roof. They were installed by Carlson's Solar of Hemet, California. They are configured as three strings of four panels each. Each panel consists of 36 cells producing a nominal 12VDC under load, so each string produces a nominal 48V (the no-load voltage is considerably higher, about 80V).
The roof on which the panels are mounted slopes to the south-southwest at about 20 degrees. Ideally they would face due south, but that would have required more complex mounting brackets. Besides, it is frequently cloudy in the early mornings here in San Diego, with the clouds burning off by late morning. A more westerly orientation favors the afternoon when it is more likely to be sunny. It also favors production when electric rates are at their highest (more about this later).
The panel cabling is 10-gauge 2-conductor Type TC cable, moisture and sunlight resistant. The cables penetrate the roof in a conventional weatherhead used for utility service entrances. The cabling goes in 1" flex conduit to a Trace TCB10 PV Combiner Box in the attic. Three #6 wires (DC +, DC- and ground) run from the combiner box in 1" flex to the garage.
System Electronics
The array power enters the back wall of my garage, where I installed a Trace SW4048 sinewave inverter, a Trace DC disconnect, a 48 volt 220 amp-hour battery bank using Trojan T-105 commodity golf cart batteries, and a Crusing Equipment Company E-meter battery monitor. A conventional AC subpanel on the inverter output feeds branch circuits around the house with various "protected" loads, such as my computer and networking gear and my VCR (so I won't lose my programs in the event of a power failure!)
 
Here you can see the back wall of my garage. The conduit from the arrays is at the right side of the photo; it enters the DC breaker panel (the upright rectangular white box with a horizontal green stripe). After passing through circuit breakers, the array power flows to a Trace Photovoltaic Ground Fault Protector , an overpriced and largely useless device that is nonetheless required by section 690-5 of the National Electrical Code. The PVGFP is mounted in the grey box at the lower right.
After passing through the PVGFP, the array power flows through a relay in the PVGFP mounting box. This relay opens whenever the battery voltage exceeds a programmed level.
Under normal operation, the relay is always closed as any excess power from the arrays is automatically sold back to the utility. This keeps the battery voltage from ever reaching the point that would open the relay. But this relay is important to protect my batteries in the event the grid is not available as a "diversion load". E.g., the inverter could fail, a circuit breaker could open, or the grid could go down.
The relay does lack two features of a solid state controller: a multi-stage battery charging program, and a nighttime cutout. Because my system is grid tied, the multistage battery charger program is not very useful to me. My batteries are normally fully charged, and if they aren't (e.g., after a power failure) the Trace inverter already has a multistage battery charger. The lack of a nighttime dropout means that unless I open the array breaker at sundown, I'll get about 200 mA (about 10 watts) of backfeed from the battery into the panels at night. I could stop this with diodes on the panel feeds, but the power loss is so small that I would probably lose more during the day in the voltage drop across the diodes than I'd save at night. The relay coil itself draws another 2-3 watts.
The batteries are in the brown box at the bottom center of the photo. I made the box out of 3/4" MDF (medium density fiberboard). The top slopes up toward the back to encourage hydrogen gas produced by the batteries to flow into the 3" vent line connected to the left rear corner of the top of the box. This line carries the hydrogen to just below a turbine vent in the roof of my garage. (Personally, I believe hydrogen in a garage is a lot less dangerous than ordinary gasoline; while gasoline vapors collect and linger near the floor, hydrogen rapidly dissipates. But the inspector made me do it anyway.)
The battery is connected back through the DC breaker box through a big 175A circuit breaker to the Trace inverter, the big white box just above the DC breaker panel. Because the inverter can carry substantial power, the cables here are quite heavy (2/0).
The two grey boxes at the top center of the picture are conventional AC subpanels. The one on the left is an existing garage subpanel I put in when I got my EV1 and I installed the Magnecharger EV charger (on the left side of the picture). The right-hand subpanel is connected to the output of the inverter and supports the special branch circuits for the "protected" loads (protected against power failure, that is).
The black cord hanging from the left side of the inverter is for a generator. In the event of an extended power outage, I can set up a portable generator and use it to supplement the power from the solar arrays to operate the protected loads and to recharge batteries.
Batteries
Here's a view looking down into the battery box.
 
The interconnects are 2/0 building wire from Home Depot. It was relatively cheap ($0.85/foot) but a real pain to work with; very stiff and unforgiving. The cables leading out of the box on the right side are 2/0 flexible "boat cable". It is much easier to work with, but it is very expensive ($7.50/foot at Boat/US, a local marine store). The yellow cable is for a battery temperature sensor affixed to the battery on the right rear. The blue wire taps the battery at the mid-point to supply 24VDC for the e-meter; note the in-line fuseholder near the battery terminal. Although tapping a battery like this can theoretically cause the pack to become unbalanced, in practice the drain low enough that the imbalance is is quickly corrected by routine battery equalization.
The bottom of the battery box consists of three 2x6s with gaps between to allow air to circulate up from ventilation holes drilled in the sides of the box. Under the box is a sheet of polyethylene to catch any acid spills. Before putting in the batteries I sprinkled a box of baking soda into the box to help neutralize any spilled acid.
DC wiring
Here's a closer look at the DC breaker panel:


The E-meter is mounted in a 2" knockout on the upper left side. The 175A inverter breaker is in the center of the box. The array comes in on the right side through 1" flexible conduit, and the 2/0 cables to the inverter leave in 2" PVC on the upper right. Note the white tape around one of the inverter cables indicating that it is a grounded neutral. It is connected to a 500A 50mV battery current shunt for the E-meter. To the right of the same taped cable is a negative bus bar. The array negative leads connect here.
The three array hot leads (red) go to 15A DC circuit breakers mounted at the upper right, upper left and lower left. The combined output of these three breakers passes down to the PVGFP mounted in the grey box at the lower right.
PV Ground Fault Protector

This is the ground fault detector. It is nothing more than two mechanically ganged DC circuit breakers. The one on the right trips at 1 amp; the one on the left is actually a switch rated at 100 amps. The 1-amp breaker is shunted by a 50 kohm resistor. When closed, the 1-amp breaker connects the negative DC bus (the white wire, signifying that it is the system neutral) to earth ground (the green wire with a yellow stripe); this is the only place where the DC neutral is grounded. The 100A switch connects the combined array output to the input of the charge controller.
The black device hanging off one of the red wires is a clamp-on DC ammeter measuring array output current.
In the event of a fault between a positive lead (battery or array) to ground in excess of 1 amp, the 1 amp breaker will trip and open the 100A switch with it. This will interrupt the ground fault except for a small amount of current that will continue to flow through the resistor. And when the 100A switch opens, the arrays are isolated from the charge controller.
Why is this pretty much useless? Because one could block any ground fault currents from flowing by merely not grounding the negative lead in the first place! A resistor (such as the 50 kohm unit here) could serve to reference the negative lead to earth ground. Under normal conditions no current would flow through the resistor, so there would be no voltage drop across it. An indicator light could serve to warn of a ground fault if desired, but the system could continue to operate normally.
As far as I can tell, the only function of the 100A switch is to get your attention by disabling the solar panels. The most credible ground fault scenario involves shorts within a panel string to the grounded panel frame, or perhaps a ground fault within the array wiring. Opening the positive array lead at this downstream point does nothing to interrupt the fault current.
The Charge Controller
A conventional PV charge controller is nothing more than a fancy semiconductor power switch between the arrays and the battery. When the battery voltage falls below a predetermined setting, the switch closes to allow the arrays to charge the battery. When the voltage rises above this point, the switch opens to protect the battery against overcharging.
In normal grid-tied operation, any excess power from the arrays is automatically sold to the utility so this switch should be closed at all times. But if the system is for whatever reason unable to sell power, the charge controller will disconnect the arrays. This could happen if the inverter fails, the DC breaker opens, the AC disconnect or circuit breaker opens, or the grid loses power.
For a time I considered getting a peak-power-tracking controller such as that sold by Fire, Wind & Rain. A peak power tracker operates the arrays at whatever voltage produces maximum power, rather than always operating them at the battery voltage. Depending on the battery condition, solar illumination and panel temperature, this could produce up to 20% additional power.
But while I waited for these units to become available, I did some measurements and calculations that told me that a peak power tracker wouldn't do much for me. Here are some notes that explain why.
So I eventually decided on a simple electromechanical relay, controlled by an auxiliary relay in the Trace inverter.
I have a TINI (Tiny InterNet Interface) single-board computer from Dallas Semiconductor that I plan to integrate into my PV system. One of its functions will be to control this relay, closing it at dawn and opening it at dusk.
The Utility Interface

Here we see the main electrical panel on the side of my house. The red signs and their wording were a SDG&E requirement, as was the disconnect switch (grey box in the lower right). They want to be able to disconnect my inverter from the grid and lock it in that state to protect their workers during a power outage when they could otherwise assume that the lines are dead. The Trace inverter has a half dozen different ways to detect a grid outage and disconnect automatically from the grid, but I can't fault SDG&E for being conservative.
The watthour meter is a GE kVS solid-state time-of-use meter that is actually quite sophisticated. It is programmed to implement SDG&E's Time of Use Rate for Households With Electric Vehicles.
Net Metering with a TOU Tariff
With time-of-use metering, the amount I am credited for each kilowatt-hour I sell back to SDG&E is a function of when I produce it. Electric rates are normally highest on sunny summer afternoons when air conditioners are running at full tilt, and this is precisely when photovoltaic systems produce their maximum output.
While I already had a TOU tariff thanks to my EV1, I learned to my dismay that only SDG&E's standard domestic tariff had net metering provisions; their existing TOU tariffs did not provide for net metering. This was disappointing, but not too surprising. After all, the utilities have never been all that enthusiastic about buying (as opposed to selling) electricity at the regular retail rate, so I could see how they'd be even less happy about buying at the even higher peak afternoon TOU rate.
Nevertheless, I read the California net metering statute as requiring the utilities to provide for net metering on all of their tariffs, including TOU. Vince Schwent at the California Energy Commission, who drafted the original net metering statute, agreed once I pointed out that it had been recently amended. I stood my ground with SDG&E, and after some deliberation they agreed to amend their TOU tariffs to provide for net metering. This new tariff went into effect into late August 1999. Finally, the sauce for the goose could become the sauce for the gander!
The pre-July 1999 EV-TOU-2 rate had a very high differential between the on-peak (noon-6pm) and super-off-peak (midnight-5am) summer rates: 32 cents/kWh and 4.2 cents/kWh, respectively. Not only did this very high afternoon rate make the economics of a PV system look better than ever before, it would have made economic sense to charge up my battery bank from the grid at cheap nighttime rates and sell it back to them during the afternoon at the premium peak rate! (This is not actually such a crazy idea; many utilities do the same thing with "pumped storage" plants.)
Electricity Deregulation - My System Pays Off!
On July 1, 1999, SDG&E finished selling off its conventional power plants as required by California's move to electricity deregulation. SDG&E is now a "Regulated Utility Distribution Company" (UDC) that no longer generates its own electricity. They buy it wholesale on the California Power Exchange (PX) at the going market price and tack on a per-kWh markup, regulated by tariff, to cover transmission, local distribution, energy losses and other miscellaneous costs. With a TOU meter, this UDC markup depends on time of day, but the difference is only a few cents/kWh.
The TOU meter is also used to determine the PX component of the total price. For example, the EV-TOU-2 on-peak period is noon to 6pm, so my per kWh energy charge for that period is based on SDG&E's average cost of buying electricity from the PX during the afternoon.
During the summer of 1999, a SDG&E price cap was in effect that hid the wide daily and seasonal swings in PX prices, thwarting my "battery sellback" scheme and decreasing the payback rate of my PV system.
The price cap was lifted in the summer of 2000, so the consumer now sees the PX prices directly. And, just as many people had predicted, the PX prices went through the roof. This happened thanks to hot weather, a shortage of generators and transmission lines, and a lack of meaningful competition in the now-deregulated generating market. The resulting dramatic rise in electric bills quickly became a hot local issue, with many angry protests and avowed refusals to pay bills. As this is written (late July) here are the prices under the EV-TOU-2 tariff:
   PX (energy) SDG&E markup Total (cents/kWh)
On-peak (1200-1800) 23.1 8.438 31.5
Off-peak (1800-0000,0500-1200) 11.1 6.183 17.3
super-off-peak (0000-0500) 4.7 5.879 10.6

So not only do the economics of PV power generation suddenly look attractive again, but so does on-peak battery selling!
But the plot continues to thicken. SDG&E has proposed a new set of tariffs that would temporarily lower the UDC component, apparently to comply with a PUC mandate to refund some excess revenues. For the regular (non-TOU) domestic rate, the decrease is about 2.6 cents/kWh. Here are the current and proposed summer numbers for the EV-TOU-2 tariff:
   Current Proposed
On-peak 8.438 -2.538
Off-peak 6.183 4.425
Super-off-peak 5.879 5.364

That's right, not only are SDG&E's proposed on-peak rates less than the off-peak rates (exactly backwards from the usual), but the proposed on-peak rate is actually negative! Not only does this again act to level out the day/night differential that encourages peak period battery selling (though this may not be enough to overcome sufficiently high peak PX prices), it also penalizes me for being a net energy producer during the peak period, when every kilowatt counts.
There are, of course, two interpretations of this proposal. One, SDG&E is trying to give us EV drivers a little break when we're forced to charge our cars in the afternoon. Two, SDG&E has been reading my web page and has finally figured out a way to retaliate for my "sauce for the goose" remarks. You decide.