Energy Efficiency

What is Energy Efficiency?

Energy efficiency is obtained through innovation. It is done by developing new methods that use less electricity to obtain the same outcome. In other words, it makes products more efficient.

Energy efficiency can include updating systems to use energy at a more efficient rate, including large-scale infrastructure.

How Energy Efficiency is Employed
Solution 1:

In both residential and commercial buildings, heating and cooling is a major cause of energy waste. 35% of the total building energy goes to air conditioning, mainly due to lacking or outdated design, which causes either hot or cold air leakage. Improving the insulation of the building requires to heat/cool it. 


Windows are one of the most difficult but most important ways to improve insulation. The ideal window design should have good thermal insulation, let enough light in, and let heat in when useful but block it when it would add to cooling loads. A building that is more often cooled should have windows that let less heat into the building. There has to be a mixture of current and innovative technologies to achieve these goals. Lowering the U-factor—the rate at which non-solar energy flows—is an important start. Metal frames (the most common frames) have a high U-factor. To lower it, a "thermal break" is necessary, which is a plastic strip in between the frame and the sash. Other materials may also make up the frame, such as fiberglass, which has air cavities than can be filled with insulation.

The second part of window efficiency is the actual glass (glazing). A common technique is called insulation glazing (IG), which is where there are multiple panes of glass that are airtightly sealed (hermetically sealed). As a result, heat gets trapped between the panes, thereby insulating the window. However, there is a new technology emerging. Vacuum insulated glazing (VIG) technologies are systems that have a space entirely devoid of matter between the two panes of glass, maximizing the insulation as no gas can enter the system, and therefore no convection can occur. This technology has a lower U-value than standard IG technologies; it could bring the U-value from 1.2 to 3.3 W/m•m•K down to at most 1.0 W/m•m•K. Traditional IG technologies can not go lower than 1.0 W/m•m•K due to the complicated heat transfer mechanism. One Korean study found that the total annual heating energy demand for each household in the Korean Capital region was 6001, 3273, 2546, and 2182 kWh for IG double-pane windows, triple-pane windows, and quadruple-pane windows, respectively. Meanwhile, the heating energy demand for a 0.7 W/m•m•K VIG system was 1273 kWh, and the heating energy for a 0.2 W/m•m•K VIG system was a mere 364 kWh, a 1,548% decrease from the double-pane windows. These numbers show that a VIG system can significantly decrease the U-value, thereby drastically lowering the energy requirements. 

Solution 2:


High Efficiency LED Lighting Systems

Both commercial and residential buildings require a lot of electricity for lighting; 11% of total building energy. Commercial buildings in particular have to light large spaces and for long periods of time. The most common lightbulb—particularly prevalent in commercial buildings—is the standard incandescent bulb. These lightbulbs are inefficient; 99% of the electricity they use is wasted as heat energy. Owners are forced to use more electricity for lighting. However, compact fluorescent lightbulbs (CFLs) and light-emitting diodes (LEDs) are more efficient than incandescent lightbulbs. LEDs last 28.83 times longer an incandescent bulb and require 85.83% less electricity. CFLs last 8.3 times longer than an incandescent bulb and require 76.6% less energy. These lightbulbs, therefore, use less electricity and are more efficient, cutting down on electricity requirements.


Baldwin, Sam, et al. Chapter 5: Increasing Efficiency of Building Systems and Technologies. In: Quadrennial Technology Review: An Assessment of Energy Technologies and Research Opportunities. United States: Department of Energy, 145-182.

Baek, Sanghoon, and Sangchul Kim. “Potential Effects of Vacuum Insulating Glazing Application for Reducing Greenhouse Gas Emission (GHGE) from Apartment Buildings in the Korean Capital Region.” Energies 13, no. 11 (2020): 2828.

“Window Types and Technologies.” Department of Energy. Accessed June 21, 2020.

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