1. Energy, Energy Measurement and Calculations

2. Energy: the ability to do work
- movement, heating, cooling, manufacturing
Types:
Electromagnetic: light – solar power - photovoltaics
Thermal: Heat – geothermal
Kinetic: motion – turbines
Nuclear: breaking apart nuclei
Electrical: energized particles (electrons)
Chemical: coal, oil, natural gas, galvanic cells (batteries)

3. Sources of Energy:
Renewable and Non-renewable:
Non-renewable:
Oil
Coal
Natural Gas
Oil Shale and Sand
Fissionable Material (Nuclear)

4. Renewables:
Solar: Solar Panels and Solar Heat
Wind
Water: Hydroelectric dams, tides
Geothermal
Biomass: plant material
Biofuels: oil and gas made from plant and animal material

5. Net Energy
Definition: The total useful energy available from the resource over its lifetime minus the amount of energy used (1st law of energy), automatically wasted (2nd law of energy) and unnecessarily wasted in finding, processing, concentrating and transporting it to others.

6. Measuring Energy HEAT:
1 Food Calorie = 1 kilocalorie (1 kCal or 1 Cal) = 1000 calories
1 calorie = the amount of heat required to raise the 1 gram of water 1 oC
As a measure of heat 1 calorie = Joules
1055 Joules = 1 BTU (British Thermal Units)

7. Measuring Energy
Electrical Power = Watt = amps x volts Amp = the number of electrons flowing through the wire = current
1 amp = × 1018 electrons passing a point at one time
Volts = the force of the electrons (pressure)
Watt = Joules/sec
THIS IS A RATE NOT AN AMOUNT

8. Watts (the rate the work is done) = Amps (the resources consumed) times Volts (the strength of the resource units)
Analogy: Water coming out of a hose.
Amount of water = Amp Pressure of the water = Volts Rate of Flow = Watts Rate is a combination of the Amount and the Pressure.

9. Electrons do the work and the more that come through a gate and the speed at which they pass through, the more work (watts) can be done. The gate restricts how many electrons can pass through at the same time. The gate (wire) size dictates this number and think of this number as amps. Now the electrons can flow through the gate at different speeds (voltage) and the faster they go through, the more energy or power they impart (Watts). Watts = Amps X Volts It helps to think of the electrons moving through the wire and see that amperage capacity is a function of wire size (how many electrons can fit in the gate or tunnel cross section) and the speed at which they are moving as the voltage or velocity.

10. Understanding How Electricity Is Generated
Metal wires have free moving electrons in them that can be moved by other electrons pushing on them or magnets forcing them to move.
The moving electrons = electric current
The faster they move = higher voltage
The more that move = higher amperage

11. Most electricity is generated using a turbine that moves magnets inside coils of wire.
As the magnets move, they move the electrons in the wire causing the electric current.

12. Utility companies usually measure in kilowatts 1 kW = 1000 W
Electricity is billed by the amount used (demand) and the time it was used (kWh)

13. Understanding Electricity Billing
Watts The rate of electrical use at any moment is measured in watts.
For example:
A 100-watt light bulb uses 100 watts or 100 J/s.
A central air conditioner uses about 3500 watts or 3500 J/s.

14. Watt-hours To know how much energy you're using you have to consider how long you run your appliances. When you run a 1-watt appliance for an hour, that's a watt-hour (Wh).
One 100-watt light bulb on for an hour is 100 Wh
One 100-watt light bulb on for five hours is 500 Wh
Five 100-watt light bulbs on for an hour is 500 Wh

15. Why is 100 Wh a measure of power?
Watt = J/s
# Watts X 1 hour (3600 sec) = # Joules
If Joules = BTUs = Energy from Coal

16. Kilowatt-hours 1,000 watt-hours is a kilowatt-hour (kWh).
For example. Ten 100-watt light bulbs on for an hour, is 1 kWh (10 bulbs x 100W x 1h= 1000Wh = 1 kWh)
Running a 3500-watt air conditioner for an hour is 3.5 kWh.

17. Note the difference between kilowatts and kilowatt-hours
Note the difference between kilowatts and kilowatt-hours. kilowatt = rate of power at any instant kilowatt-hour = amount of energy used for a given amount of time
A light bulb doesn't use 60 watts in an hour, it uses 60 watt-hours in an hour. Since utilities measure usage for an entire building, they use kilowatts or thousands of watts. Utilities refer to the monthly kW reading as demand.

18. Demand is the actual wattage consumed.
Most utilities charge residential and small commercial customers only for the energy, or kWh, they use in a month. However, for larger commercial and industrial customers, most utilities will base the charges on both the energy and the monthly demand reading.

19. Utilities base the demand charge on the highest fifteen or thirty minute average demand that occurs during a month. Sometimes a rate schedule is set up to include a " billing demand". The billing demand is the highest of either the current month's demand or a percentage of the highest demand from the previous eleven months.

20. How much does electricity cost?
The cost of electricity depends on where you live, how much you use, and possibly when you use it. There are also fixed charges that you pay every month no matter how much electricity you use.
For example, $6/mo. for the privilege of being a customer of the electric company, no matter how much energy used.

21. These figures include a fuel charge of 2.265¢ per kWh.
Most utility companies charge a higher rate when you use more than a certain amount of energy, and they also charge more during summer months when electric use is higher. As an example, here are the residential electric rates for Austin, Texas (as of 11-03):
These figures include a fuel charge of 2.265¢ per kWh.
First 500 kilowatts hours
5.8¢ per kilowatt hour (kWh)
Additional kilowatts hours (May-Oct.)  
10¢ per kilowatt hour
Additional kilowatts (Nov.-Apr.).
8.3¢ per kilowatt hour

26. An additional charge based on the maximum amount of electricity you draw at any one time. This is called a demand charge. The following chart from Wisconsin Electric illustrates the concept. The shaded area is how much electricity you used, and you know you get charged for that. But the black bar on top is the demand, how much energy you "demanded" at any given point throughout the day. If your utility company has a demand charge (ask them), then you can save money by spreading out your electrical use. For example, run a washing machine and dryer one after the other rather than at the same time. And better yet, run them when you're not using much electricity for other purposes (such as at night when the air conditioner is off).

27. Calculating Energy Costs and Savings
Example 1 A small commercial customer replaces watt incandescent lamps with watt fluorescent lamps. The lamps operate eight hours per day, five days per week, year round. Their utility charges them $0.08/kWh. To calculate the energy savings, just figure the difference between the existing energy usage and the proposed energy usage.

28. Existing Energy Usage 100 lamps times 60-watts per lamp 8 hours per day Five days per week 52 weeks per year 1000 watts per kilowatt

29. The Proposed Energy Usage
100 lamps 15-watts per lamp Eight hours per day Five days per week
52 weeks per year watts per kilowatt

30. The Cost Savings To calculate the cost savings, just multiply the annual energy savings times the charge per kWh for electricity (eight cents in this case).

31. Example 2 Let's take this same scenario, but this time let's assume there is an additional demand charge of $9.75/kW.
Demand Savings equals existing demand minus proposed demand

32. Existing demand 100 lamps times 60-watts 1000 watts per kilowatt.

33. Proposed demand 100 lamps 15-watts per lamp 1000 watts per kilowatt
Demand savings per month and per year

34. Example 3 If a customer's maximum or peak demand occurs at 2:00 PM because of air conditioning, and the lights are operating on a time clock from 6:00 PM to 6:00 AM, then the lights do not contribute to the peak demand. Making a change to the lighting demand does not affect the customer's demand charges. For example, the previous situation of 100 lamps being changed would save only energy costs, not demand if these lamps are located outdoors and operate only at night.