Electrochromic Smart Windows Unlock Energy Efficiency and Comfort: Real-Life Case Studies

Your windows are about to change. The next generation of energy-efficient windows, electrochromic windows (“eWindows”) or smart windows, are replacing their conventional predecessors as builders and homeowners realize the enormous advantages of installing these energy-saving alternatives. eWindows control the amount of natural light entering your home or office by tinting at the touch of a button, making them an essential addition to any smart building.

The heating, cooling, and lighting of buildings account for 27% of global CO2 emissions—installing eWindows can reduce gigatons of these emissions annually. As smart windows have grown in popularity over the past few years, so too has data that shows how they save energy, reduce costs, and regulate indoor temperatures—making them a necessary component for decarbonizing buildings.

Three key points have emerged from recent studies that demonstrate how eWindow installations save energy and provide unparalleled comfort:

1. Smart windows increase building energy efficiencies in all climates

Smart windows reduce the heating and cooling loads of buildings in cold, warm, and hot climates. Recent studies have consistently shown significant energy savings:

  • Singapore’s Tropical Test: eWindows deployed in large-scale prototyping chambers  enabled 19% energy savings compared to single-glazed windows.
  • Tehran’s High-Rise Office Building: Simulations assessed eWindows’ impact on a high-rise office building and showed energy consumption reductions of up to 14%.
  • Seattle’s Seven-Story Office Building:  A year-long study demonstrated 18% energy savings by integrating eWindows in a 45-year-old, seven-story office building.

These findings align with other research conducted, including simulations that demonstrated average energy savings of 10% in office buildings across major U.S. cities and a remarkable 39% energy savings in a south-facing perimeter office in the San Francisco Bay Area. Simulations for buildings in Helsinki, London, and Rome showed average energy savings of 36%.

2. Smart windows reduce cooling equipment costs

Energy savings are only part of the story. eWindows also enabled significant reductions in cooling equipment costs by minimizing heat infiltration during the hottest parts of the day:

  • Minneapolis, Phoenix, and Washington, DC: A 2010 simulation demonstrated that eWindows could cut cooling equipment costs by 30-35% in new construction and 40-50% in retrofits across different climates.
  • Denver, Colorado: In 2013, a low-rise office building saw a 20% reduction in cooling equipment expenses due to eWindows.
  • Stockholm, Sweden: A recent simulation suggested that eWindows can enable considerable downsizing of cooling equipment.

3. Smart windows keep interior temperatures pleasant

The impact of smart windows goes beyond numbers—it is also felt in the comfort of indoor spaces. By electronically tinting to limit excess heat, eWindows help maintain cooler room temperatures:

  • New York City Apartment: On a scorching 31ºC day, rooms equipped with eWindows felt a refreshing 6ºC cooler than rooms with traditional windows.
  • Singapore’s Prototyping Chambers: This study showed that eWindows led to a remarkable 4.4ºC reduction in interior surface temperatures.

The evidence from these real-life scenarios demonstrates that eWindows are an innovative yet practical solution for creating energy-efficient, comfortable indoor environments.

The future of windows is here, embodied in Miru eWindows. With our innovative manufacturing processes, we are committed to making game-changing smart windows more accessible than ever before. With financial incentives making eWindows more affordable than ever, now is the time for the building industry to embrace this clean technology and reduce global carbon emissions.

To learn more about Miru eWindows and how they can transform your space, contact us at contact@mirucorp.com.

The next era in window innovation — transitioning from low-E coatings to dynamic smart windows

A major shift is taking place towards windows that save energy

The energy crisis of the 1970s catalyzed the creation of one of the greatest energy saving innovations in modern history: low-emissivity (low-E) windows. Now, 40 years later, dynamic, energy-saving electrochromic windows are poised to disrupt thee windows industry — spearheaded by companies like Miru. 

The 1970s were a pivotal time in energy-saving innovation. After a series of global oil price shocks and supply disruptions, the U.S. government funded research to reduce the use of fossil fuels.

At this time, windows were a key area of focus as buildings are one of the largest energy consumers, and windows are a key source of energy inefficiency. Heat can easily pass through standard windows, leading to wasteful heat gain in warmer climates and heat loss in colder climates.

To address this, a strategic collaboration among the U.S. Department of Energy, industry associations, window manufacturers, and research institutions led to a significant breakthrough in window technology: low-E windows. 

Low-E windows contain thin, transparent coatings on the surface that reduce the amount of heat transferred through a window. These low-E coatings reflect infrared heat radiation to prevent excessive heat gain in hot weather, while retaining heat in the building during cold weather, reducing the heating and cooling costs of buildings by 20%. 

Today, more than 85% of windows contain low-E coatings, but as game-changing for energy saving as this innovation was, low-E windows are not enough. Low-E windows are static: they do not adjust for the seasons or the time of day. We still need window coverings to protect us from the sun’s glare, meaning our blinds and curtains are closed 60% of the time! 

We are now entering the next era in window innovation

Dynamic smart window technologies are now available to increase building energy efficiencies by yet another 20%. These electrochromic windows (eWindows) have been proven to keep rooms 10 degrees C cooler than conventional windows during our ever hotter summer months.

Miru is helping drive this next shift towards more energy-efficient windows. Our eWindows enable people to electronically change the tint of their windows to respond to the season, time of day or weather pattern — minimizing excessive heat during hot weather while containing heat within the building during colder weather. Miru eWindows enable us to stay connected to the outside world while still enjoying a pleasant view.

To learn more about Miru smart eWindows, contact us.

Windows for a decarbonized future

Electric vehicles and e-bikes may be in the limelight of our global move towards decarbonization, but our buildings play an outsized role in reducing our carbon emissions.

Many people do not realize that buildings consume more energy than the entire transportation sector combined—including all cars, trucks and planes. The majority of this energy goes toward heating, cooling and lighting, which accounts for 27% of global GHG emissions and generates 10 gigatons of carbon emissions annually.

This energy goes right out the window—literally. If we can improve the energy efficiency of our windows, we can make a sizable impact in reducing global carbon emissions. At Miru Smart Technologies, we are developing proprietary electrochromic window technology that electronically tints to substantially reduce the amount of energy buildings consume.

Windows are a major source of carbon emissions 

Windows are better than walls: They let in the natural light we need for our mental and physical health, and let us connect us to the outside world. But increasingly strict energy-efficiency codes are forcing builders to use more walls than windows to meet these regulations.

Unwanted heat entering or leaving through windows is responsible for 30% of space heating and cooling energy needs in buildings.

To reduce the energy our buildings consume, we need to design better windows—windows that let in natural light and views while also keeping the adequate and comfortable temperature inside.

Windows have not changed in 40 years

The energy crisis of the 1970s led to the development of the first low-emissivity (“low-E”) windows. These windows have a coat of thin metal film deposited onto hot float glass. They allow sunlight into a room while, depending on the climate, reflecting or keeping heat to help maintain the inside temperature to increase building energy efficiencies by 20%.

Today, 85% of windows sold around the world contain a low-E coating.

Market share by glazing type showing that low-E windows account for 85% of the global market. Figure updated from National Renewable Energy Laboratory (NREL) (2022, April). www.nrel.gov

Low-E windows do not change with the seasons

While low-E windows make our buildings more energy efficient, they are static. The amount of light let into the windows and the amount of heat the windows reflect does not change between winter and summer, morning, midday and evening, weekdays and weekends.

Currently, when designing the building’s enclosure, a compromise is made when selecting the glazing parameters so the windows can deliver the best performance across different seasons. This compromise leaves a lot of energy on the table. Low-E windows let in too much energy during hot summers while not taking advantage of free solar energy during cold winters.

This inefficiency becomes apparent when looking at the solar heat gain coefficient (“SHGC”) of low-E windows. SHGC is a standard used to measure the insulating properties of a window. By definition, SHGC is the ratio of solar energy that hits a window and the solar energy that enters the window. A low SHGC (<0.30) is desirable when it is warm outside, while a higher value (>0.50) is preferable when it is cold outside.

For low-E windows, you need to select a single SHGC value even though the temperature the window is exposed to will vary significantly over time.

Solar heat gain coefficient (“SHGC”) values for a variety of different glazing configurations, with higher values representing the configurations that let more solar energy through the window.

How eWindows give you control of your SHGC

It is not realistic to change our window glass each season like we do with car tires. However, a window with a SHGC that changes depending on environmental conditions can provide the energy efficiency of a range of different window tints.

The variable tint available with eWindows does this.

eWindows allow you to electronically control the SHGC of the window, so you can easily toggle between different SHGCs depending on the weather, time of day, season, or building occupation.

Plot of visible light transmittance (i.e., level of tint) vs. SHGC for various glazings to demonstrate the relationship between the degree of visible light transmittance and SHGC.

How do eWindows work?

Miru eWindows use laminated electrochromic glass units that are combined into an electrochromic insulated glass unit (“eIGU”).

The electrochromic units contain two pieces of glass, each with a metal oxide coating that changes color when charge is passed through it. The electrochromic units operate like a lithium battery: electricity drives the migration of lithium from one metal oxide coating to the other. This ion migration changes the transparency of the window from a clear to tinted state. The window can be cleared again by simply reversing the direction of electrical current.

This ability to vary the tint with applied voltage gives you precise control of the eWindow’s SHGC. The window can also be connected to an algorithm or automated thermostat to change the tint of the window with the time of day or cloud cover, all while letting you enjoy your pleasant view.

Rendering of a cross-section of a Miru eIGU showing the electrochromic unit that faces the exterior of the building, and low-E glass towards the interior of the building.

How long does the energy payback take?

eWindows contain more coatings than lowE windows, so they can be a more expensive investment up front. However, the initial eWindows’ costs are offset by the smaller investment required for the heating and cooling systems of the building. In fact, eWindows can actually reduce the overall cost of a building.

More importantly, eWindows provide significant energy and carbon savings. The energy savings from eWindows yield cost and carbon payback periods of less than two years, particularly in hot climates that need to maintain cool indoor temperatures.

For example, recent industry case studies of electrochromic glazing retrofits demonstrated that a Seattle office building saved 18% in annual energy, and a shopping mall in Colorado showed an even higher 73% reduction in energy use when eWindows were combined with lighting and envelope improvements.

Eliminate gigatons of CO2 emissions with eWindows 

Windows are everywhere. The inefficiency of these windows are responsible for massive amounts of carbon emissions.

eWindows are a clean energy technology that can provide significant energy and carbon savings today.

If every installed window was an eWindow, we would reduce global CO2 emissions by 2 gigatons per year. This would represent a reduction of global CO2 emissions by more than 5%! eWindows are a proven technology and can be deployed today. With the Biden administration’s 30% tax credit for eWindows in the 2022 Inflation Reduction Act, increasingly stringent energy-efficient codes, and growing stress on our power grids, there is more demand than supply for eWindows.

Policies are forcing the electrification of cities. The building industry must find ways to make their buildings more efficient and eWindows are an important part of the solution as the world moves toward a decarbonized future.

This article first appeared in Clean50 on August 18, 2023.

Take the longer view with Miru smart sunroofs

The number one factor consumers cite when deciding which electric vehicle (EV) to purchase is driving range. But while car manufacturers focus on improving battery designs, tintable windows also extend the driving range of an electric vehicle. By controlling the amount of light passing through the vehicle window, drivers can realize a 10% increase in EV driving range.

Smart sunroofs change the level of tint in response to electricity. The driver can therefore dynamically tint the window with the press of a button. These windows offer greater comfort in changing weather conditions, while reducing the energy vehicles consume to increase the driving range for EVs.

The first generation of smart sunroofs are finally hitting the market after years of development. Porsche Taycan and Renault Solarbay are both examples currently in the market.

The Porsche Taycan comes with optional panoramic glass roof with variable light control. Image from: www.porsche.com

While these first gen smart windows diffract light, Miru is pioneering the use of electrochromic technologies that better control the sun’s heat. Miru is bringing to market electrochromic windows (“eWindows”), which have been proven on flat glass in large commercial buildings—making Miru the first to make curved eWindows for automobiles.

Miru eWindows can span large panoramic sunroofs without bisecting busbars, and use low voltage power to drive the switching. These features are important to both consumers and manufacturers, as automobiles are designed with increasingly more glass.

By using Miru eWindows to increase the driving range of electric vehicles, drivers can reduce CO emissions, enhancing the wellbeing of our people and our planet.

To learn more about Miru eWindows for automobiles, email contact@mirucorp.com.

Reduce global carbon emissions with smart windows

Cars, trucks and airplanes are widely regarded as the worst contributors to our climate change crisis for their greenhouse gas (GhG) emissions. But buildings are actually the largest emitters of CO2 — responsible for 40% of the world’s carbon emissions.

The most significant energy draws in buildings are for heating, cooling, and lighting, which generate 10 gigatons of CO2 emissions annually. If we make buildings more eco-friendly, we can stabilize global temperatures. We need to move quickly: The global population is projected to double by the year 2050, and to meet those needs, the pace of construction is not slowing down.

Windows are a major source of building inefficiencies.

Improvements in the efficiency of a window will have a huge impact on CO2 emissions. But the last significant innovation in windows (low-emissivity or low-e windows) was 40 years ago. That’s before the first Apple Macintosh came to market. While computer technology has clearly advanced (we can now operate most of our lives with a smartphone the size of our hand), windows technology innovation has been stuck in the ‘80s.

Enter smart windows or electrochromic windows.

Smart windows significantly increase overall building energy efficiency. Compared to conventional windows with low-emissivity coatings, smart windows can improve building energy efficiency by 20% even in mild climates. In hotter regions, the energy savings can reach 40%.

Smart windows can also reduce peak heating and cooling loads significantly — by 25% or more. This means we can downsize mechanical equipment, saving even more energy and costs. When implemented worldwide, smart windows can make a material impact in reducing energy use and the carbon footprint of buildings.

To put it in perspective, if just 25% of new buildings worldwide adopted the use of electrochromic glass like in Miru smart windows, the carbon savings would exceed half a gigaton annually by 2050.

The graph below projects the carbon savings possible with varying smart window adoption rates in new building construction

It is important that the world recognize how important windows are in reducing global carbon emissions.

Miru windows efficiently control sunlight and solar heat, resulting in reduced energy consumption, lower carbon emissions, and significant cost savings for building owners. By embracing these advanced window technologies, we can make substantial strides toward a more sustainable and energy-efficient built environment.

Miru smart windows offer a game-changing solution for reducing global carbon emissions.

Miru windows highlighted as critical to help buildings meet carbon emission targets by leading propTech investor

Miru Smart Technologies, an innovator in the field of electrochromic windows, is pleased to see the growing prominence of Greensoil, a key player in Canada’s proptech sector. As a company committed to innovation and sustainability, Miru recognizes the importance of companies like Greensoil in driving progress towards a more sustainable future.

Greensoil is a proptech company that specializes in the development and deployment of advanced technologies for the real estate sector. The company’s solutions help property owners and managers optimize building performance, reduce energy consumption, and improve tenant comfort. Greensoil’s innovative approach to proptech has made it a key player in the industry, and the company has been recognized for its contributions to sustainability and innovation.

“Greensoil is doing important work in the proptech sector, and we are excited to see the company’s growing prominence in Canada,” said Curtis Berlinguette, CEO of Miru Smart Technologies. “As a company that is committed to innovation and sustainability, we recognize the importance of companies like Greensoil in driving progress towards a more sustainable future.”

Miru Smart Technologies shares Greensoil’s commitment to sustainability and is dedicated to developing eWindow solutions that help businesses reduce their carbon footprint and optimize their operations. By working together with companies like Greensoil, Miru Smart Technologies hopes to drive progress towards a more sustainable future and create a better world for future generations.

“As a company, we are committed to developing innovative solutions that help businesses reduce their impact on the environment,” added Berlinguette. “We believe that by working together with other companies that share our values, we can drive real change and make a positive impact on the world.”

Read the article here.