System Efficiency

Req 3 — Following Energy Through a System

Show you understand energy efficiency by explaining to your counselor a common example of a situation where energy moves through a system to produce a useful result. Do the following:

This requirement is about seeing the whole chain, not just one device. Pick one common system and follow energy from source to result. Good choices include a refrigerator, a bicycle and rider, a hair dryer, a home heating system, a toaster oven, or a phone charger.

A strong system for this requirement has clear parts, a clear source, an obvious useful result, and at least one important loss. If you can draw it as boxes with arrows, it is probably a good choice.

Requirement 3a: Identify the parts of the system

3a.

Identify the parts of the system that are affected by the energy movement.

Suppose you choose a refrigerator. The parts include the electrical cord, compressor, refrigerant, coils, insulated walls, interior air, food inside, and the room air around it. Energy is moving through that whole system, not just one component.

If you choose a bicycle and rider, the system parts might include your muscles, lungs, food, chain, gears, tires, road surface, and the bike frame. Even your body is part of the system because it provides the original energy.

A good test

Ask yourself, “If I removed this part, would the system behave differently?” If the answer is yes, it probably belongs on your list.

Requirement 3b: Name the primary source of energy

3b.

Name the system’s primary source of energy.

The primary source is where the chain begins. In a plugged-in appliance, that source may be electrical energy. In a bicycle, it is chemical energy from food in your body. In a gasoline lawn mower, it is chemical energy in the fuel. In a solar-powered device, it is radiant energy from the Sun.

Be careful not to confuse the carrier with the source. Electricity often carries energy, but the deeper source might be coal, natural gas, wind, water, nuclear fuel, or sunlight used to generate that electricity.

Requirement 3c: Identify the useful outcomes

3c.

Identify the useful outcomes of the system.

The useful outcome is the job you actually wanted done. In a refrigerator, the useful result is keeping food cold. In a hair dryer, it is warm moving air that dries hair. In a bicycle, it is motion that gets you somewhere. In a phone charger, it is stored energy in the battery.

This matters because efficiency is judged against the useful outcome, not just against motion or heat happening somewhere in the system.

Requirement 3d: Identify the energy losses

3d.

Identify the energy losses of the system.

No real system is perfect. Some energy always ends up where you do not want it. Losses often appear as heat, sound, vibration, friction, air resistance, or wasted light.

A refrigerator keeps the inside cool, but the compressor and coils warm the surrounding room. A bicycle gets you down the street, but friction in the chain and tires produces heat. A phone charger warms up because some electrical energy is lost before it all reaches the battery.

Putting the whole explanation together

Here is a simple pattern you can use with your counselor:

Explain your system clearly

One sentence for each part of the story

System: Name the system and what it is supposed to do.
Parts: List the major parts that the energy moves through.
Primary source: Name where the energy starts.
Useful outcome: Say what useful job gets done.
Losses: Explain where energy escapes into less useful forms.

Energy Saver The Department of Energy's practical guide to how systems in homes use energy and where efficiency improvements matter most. Link: Energy Saver — https://www.energy.gov/energysaver/energy-saver

You have mapped energy through a system. Next, you will apply that way of thinking at home by measuring real use and tracking changes over two weeks.