heat Archives - Zureli

Search for any green Service

Find green products from around the world in one place

Window cleaning

Singapore Safety Glass

How the World’s Whitest Paint Can Reduce Energy Use

Posted on March 7, 2024 by dishanth

Scientists have long understood the climate and energy efficiency benefits of reflective white paints. Now, engineers at Purdue University have created the world’s whitest paint that reflects more than 98% of sunlight, leaving all other paints appearing grey by comparison. As demand for sustainable solutions grows globally, this innovation promises greener buildings and cities by passively lowering carbon emissions and energy use.

The world’s whitest paint formulation was reportedly completed in early 2021. While initially produced for research applications at Purdue, press releases indicate Perdue intends to optimize and commercialize the product for widespread availability as early as late 2023. This rapid early adoption timeline speaks to the hunger for market-viable incremental gains in cooling efficiency as global temperatures continue rising.

With the formulas and methods published openly, it remains to be seen whether alternate whitest paint variants may emerge from other research teams or commercial producers, sparking a global race toward passive cooling innovation. Even moderate cooling boosts from white paint could incentivize entities like major cities to begin budgeting for wide-scale reflective surface projects within the decade.

Applying the world’s whitest paint to building rooftops and envelopes can reduce their surface temperatures by over 20°C compared to conventional options. By reflecting rather than absorbing heat, the broad deployment of the world’s whitest paint could mitigate the phenomenon of urban heat islands, where dense cityscapes absorb and radiate increased warmth. Modeling suggests summer city temperatures could decrease by over 2°C using this approach.

The development of a highly reflective and renewable calcium carbonate-based paint offers an innovative solution to excessive urban heating. As climate change brings more frequent and intense heat waves, the cooling potential of reflective white surfaces will grow increasingly impactful. Deploying this paint across a city’s building stock can lower indoor and outdoor temperatures while cutting air conditioning demands as well. Transitioning rooftops from heat-trapping dark colors to the whitest paint formula could become a climate resilience strategy for communities worldwide.

Looking beyond buildings, custom reflective paints and paving materials show similar potential for cooling everything from vehicles to sidewalks to transit shelters. An urban landscape covered with maximum heat reflection could compound cooling benefits compared to white rooftops alone. More research into expanding high-albedo surfaces across the built environment will further quantify the associated quality of life and emissions reductions. Simple shifts in surfaces and materials at scale could make future cities markedly more livable.

The world’s whitest paint keeps surfaces cool to the touch, even in the hottest environments. Compared to the air temperature at mid-afternoon, a surface painted with the world’s whitest paint can be several degrees cooler than regular white paint. At night, the difference is even more pronounced, up to 19 degrees.

The corresponding drop in air conditioning electricity demand is equally significant from an emissions reduction perspective. Studies by the US Environmental Protection Agency show cool roofs can reduce a building’s annual air conditioning requirements by 10-30%. The increased grid energy efficiency will provide critical flexibility for integrating renewable energy sources as part of essential decarbonization efforts across the power sector.

While the world’s whitest paint’s exceptional solar performance will justify further optimization before mass production, its imminent commercial arrival heralds a shift in leveraging incremental materials innovation. The compound benefits of collective small-scale action represent meaningful progress, offering pragmatic climate hope. If cool paint alone makes summers more bearable, our combined creative efforts focused first on the possibly more than the ideal may yet brighten prospects for sustainable living.

With vision and patience, Perdue’s ultra-white paint is but a glimpse of a future where green cities are dotted with communities that thrive in the hotter world they’ve warded off, one roof at a time.

Source Happy Eco News

Solar Farms Help Bees: Solar Installations for the Bees

Posted on March 5, 2024 by dishanth

Solar farms help bees: Solar farms emerging as sanctuaries for declining wild and honey bee populations.

In an unexpected turn, solar farms help bees and are emerging as potential sanctuaries for declining bee populations, providing a secondary purpose beyond clean energy generation. A recent study reveals that strategically planting native flowers and grasses around solar installations significantly enhances the population and diversity of crucial pollinators like bees, offering a promising avenue for both clean energy expansion and environmental conservation.

Research conducted by scientists from the Department of Energy’s Argonne National Lab, in collaboration with the National Renewable Energy Lab, focused on assessing the impacts on insects from two large solar installations situated on retired farmland in Minnesota. Enel Green Power North America, the operators of these solar sites, undertook the initiative to plant wildflower mixes alongside the panel arrays during construction in 2018. The researchers then conducted comprehensive year-round insect surveys at these facilities from 2018 to 2022.

The findings from the study are nothing short of remarkable; solar farms help bees. Over the five-year observation period, both native bee and monarch butterfly populations increased more than twenty-fold. The areas surrounding the solar panels transformed into thriving, prairie-like habitats abundant with essential flowering nourishment. The overall insect populations tripled, surpassing initial expectations. Additionally, these flourishing hubs of pollinators are extending benefits to vegetation in nearby agricultural areas, as evidenced by satellite imaging.

Dr. Lee Walston, an ecologist at Argonne and the lead author of the study, expressed enthusiasm about the scale of positive influence managed solar landscapes can have on insect biodiversity and abundance. The strategic integration of natural ecosystem elements adjacent to renewable projects, as demonstrated in this study, could potentially offer a win-win scenario, supporting the expansion of clean energy infrastructure while addressing the decline in insect populations.

The research underscores the concept of “solar sharing” – a departure from the traditional approach of isolating solar infrastructure from its surroundings. By allowing vegetation to thrive around solar facilities, solar farms help bees, and a new haven is created to support fragile bee colonies. The collapse of global bee populations poses a severe threat to agriculture, as over $500 billion in crop production relies on natural pollination annually.

But it doesn’t have to be only about the bees. Agrovoltaics refers to co-locating agriculture and solar photovoltaic systems on the same land. The solar panels are elevated and spaced out to allow crops to be grown underneath while allowing sunlight to reach the crops. The partial shade created by the solar panels can benefit certain crops by providing shelter, reducing evapotranspiration, and lessening weed pressure. The crops benefit the solar infrastructure by reducing heat under and around the panels.

Some bee-friendly crops and flowers that could thrive under the partial shade of solar panels include potatoes, cabbage, kale, carrots, Brussels sprouts, celery, spinach, onions, garlic, lettuce, arugula, strawberries, asparagus, leeks, swiss chard, parsley, oregano, green beans, sunflowers, cosmos flowers, marigolds, clovers, borage, and many varieties of wildflowers. These provide nutrient-rich pollen and nectar that support diverse bee populations.

These findings open the door to a new perspective on the relationship between solar power and ecological conservation. Instead of erecting barriers, solar infrastructure can be designed to coexist harmoniously with the environment. The success observed in this study suggests that solar farms help bees and can play a crucial role in aiding declining bee populations, offering hope for preserving essential pollinators.

As the world grapples with the urgent need for sustainable practices amid the climate crisis, the authors hope these groundbreaking findings will inspire further research. Exploring habitat-friendly solar blueprints to integrate nature into the urgent climate transition could be a transformative step forward. Dr. Walston emphasized the potential symbiosis between solar power and ecological conservation, envisioning bees flocking to blossoms beneath solar panels, which may reveal surprising pathways to advance sustainable energy and agriculture concurrently.

In conclusion, solar farms help bees. Once seen solely as agents of clean energy, they are now emerging as potential allies in the crucial mission to preserve and protect bee populations. This unexpected synergy between renewable energy infrastructure and environmental conservation opens doors to innovative solutions that could redefine the future of sustainable energy and agriculture.

Source Happy Eco News

Intel is using hot water to cut natural gas use in its factories

Posted on January 29, 2024January 29, 2024 by dishanth

Intel’s new manufacturing plant in Leixlip, Ireland, which cost $18.5 billion to build, is replete with technologies touted for conserving energy and water including programmable, all-LED lighting and a water reclamation and filtration system that could save 275 million gallons a year.

One of its more unusual features, however, is an approach that’s often overlooked: capturing heat generated by equipment in the facility and funneling it into production processes rather than expelling it through cooling towers. This was accomplished by the installation of recovery chillers that capture heat created by Intel’s high-temperature manufacturing processes and pipe it in the form of heated water to other places at the facility.

Intel estimates these heat recovery measures will allow it to significantly cut the natural gas it must buy to run operations at the site, Fab 34. It will use nine times as much recovered energy than what is generated by other fuels, the company projects. That so-called “waste heat” can be used for tasks such as preheating the ultra-pure water Intel needs for semiconductor fabrication or keeping buildings at the site warm during cooler weather, said Rich Riley, principal engineer in Intel’s corporate services development group.

“If we didn’t have that heat, we would need that much more gas to facilitate the [heating, ventilation and air-conditioning] operations,” Riley said. “This is an overall reduction of natural gas consumption.”

Over time, Intel’s plan is to build on heat recovery and other energy efficiency measures by updating them with industrial equipment, such as heat pumps, that run on electricity.

Intel’s near-term energy-related sustainability goals include reducing Scope 1 and 2 emissions by 10 percent by 2030 from a 2019 baseline (it has achieved 4 percent as of fiscal year 2022); and conserving up to 4 billion kilowatt-hours cumulatively.

An untapped source of energy efficiency

Intel hasn’t disclosed the potential impact on its carbon emissions this heat recovery at Fab 34 effort could have, but a retrofit using water-to-water heat pumps in Fab 10 (also in Leixlip) will save an estimated 18.3 million kilowatt-hours of electricity annually. It will reduce Scope 1 emissions by about 4,760 metric tons, but Scope 2 emissions will increase by about 1,627 metric tons because of the electricity needed for the heat pumps.

Industrial energy remains a thorny challenge for corporate sustainability teams: An estimated 20 percent to 25 percent of energy consumed globally by industrial sources is still predominantly powered by coal and natural gas, according to the International Energy Agency.

The potential energy cost savings of using recovered waste heat for industrial processes, district heating applications or to generate electricity could reach up to $152.5 billion annually, slightly less than half the value of the natural gas imported by the European Union in 2022, according to a McKinsey report published in November. The analysis estimates the global recoverable heat potential is at least 3,100 terawatt-hours.

“In our view, if you want to decarbonize, heat recovery and waste heat is one of the most economical levers available,” said Ken Somers, a McKinsey partner who was one of the report’s authors. One barrier to adoption has been low natural gas prices, but tariffs and supply shortages have prompted companies to rethink their dependence, he said.

The industrial heat pump technology needed to move heat from where it’s generated to where it’s needed in a production process is also maturing. The potential for manufacturers of chemicals, consumer products, food and pharmaceuticals to use this approach is growing as a precursor to the electrification of production systems, said Patricia Provot, president of thermal production equipment manufacturer Armstrong International.

“If your plan is to fully decarbonize, your first step is to get rid of steam and use hot water, and then try to recover as much of that waste heat as possible and put it back into the system,” Provot said.

Source GreenBiz Group Inc

6 Types of Cool Roof Technology

Posted on August 15, 2023 by dishanth

Cool Roof Technology: a Low-cost Way to Reduce Energy Consumption and Carbon Emissions

Want a huge decrease in carbon emissions, a reduction in summertime cooling costs and a more efficient home? Cool roof technology can do all that. Cool roof technology has the potential to eliminate billions of tons of carbon dioxide at a very low cost.

If you’ve ever spent time on a black asphalt roof or up in an attic during the heat of summer, you understand how much heat energy is added to a home during summer months. This is heat that many of us pay to remove by using air conditioners and other means.

But what if, just by a better design and choice of materials, we could have a far cooler house that uses far less electricity each month? That is what people in the Mediterranean and other hot climates have been doing for centuries. White paint and chimney-style ventilation that distributes cool air from lower areas of the house are low-tech examples of cool roof technology that works.

Modern cool roof technology is similar. Most are just like regular roofs but are designed to reflect sunlight and shed heat, to keep buildings cooler in the summer. According to a study by the National Renewable Energy Laboratory (NREL), cool roof technology could reduce energy consumption for cooling by up to 20%. The study also found that energy savings from cool roof technology could eliminate up to 1.4 billion tons of carbon dioxide emissions annually in the United States. The equivalent of taking 300 million cars off the road!

According to Lawrence Berkeley National Laboratory, if all North American cities with populations over 1 million people adopted cool roof technology, air conditioner use would fall by one-third.

The Human Cost of Heat

The savings aren’t just in terms of money and carbon emissions. Climate change has disproportionately increased temperatures in urban areas. An urban landscape largely covered in asphalt, concrete and black roofing materials is far hotter than one covered in greenery or reflective materials, a phenomenon known as the urban heat island effect.

The urban heat island effect is the phenomenon of cities being warmer than surrounding rural areas. This is because cities have more dark surfaces, such as black roofs, which absorb sunlight and heat up the air. The heated air then rises, creating a convection current that draws in cooler air from surrounding areas. This process can lead to increased temperatures in cities, which can have a number of negative consequences, such as increased energy consumption for cooling, decreased air quality, and increased heat-related illnesses and deaths.

Black roofs also radiate energy directly into the atmosphere. This energy is then absorbed by clouds and trapped by the greenhouse effect, further contributing to global warming.

Type Depends on Location Climate

There are a number of different types of cool roof technology available, including:

Reflective roofs: Reflective roofs are the most common type of cool roof. They are made of materials that reflect sunlight, such as white or light-colored tiles, metal roofs, or paints. Reflective roofs can reflect up to 90% of the sun’s heat, which can help to keep buildings cooler in the summer.
Evaporative roofs: Evaporative roofs are made of materials that allow water to evaporate, such as clay tiles or metal roofs with a water-absorbing coating. As the water evaporates, it cools the roof and the building below. Evaporative roofs can be effective in hot, dry climates.
Phase-change materials: Phase-change materials are materials that change their state from solid to liquid and vice versa. When these materials change phase, they absorb or release heat. Phase-change materials can be used in cool roofs to store heat during the day and release it at night. This can help to keep buildings cooler in the summer and warmer in the winter.
Cooling paints: Cooling paints are paints that are applied to roofs to make them more reflective and to help them cool down. Cooling paints are effective in hot, sunny climates and typically contain titanium dioxide, a highly reflective pigment.
Cooling granules: Cooling granules are small, reflective beads applied to roofing materials like shingles. The granules reflect sunlight and help to keep the roof cooler. Like cooling paints, cooling granules are most effective in hot, sunny climates.

Green Roofs are Cool Roofs

Another type of cool roof technology is the green roof. Green roofs are made of a waterproof membrane with a layer of soil and vegetation on top that helps to insulate the roof and reflect sunlight. Green roofs can reflect up to 70% of the sun’s heat, which can help to keep buildings cooler in the summer. In some cases, they can provide vegetable gardens or just a nice place to sit and enjoy the feeling of being surrounded by nature – while in the city.

Green roofs also have the effect of providing bird and pollinator habitat as well as reducing stormwater runoff. Because of the benefits, many cities are now mandating the installation of green roofs on new construction. New York, San Francisco, Chicago, Seattle and Portland all require green roofs on new construction on buildings with roof areas over a specific set size. That said, retrofitting an existing building is often cost prohibitive due to the structural requirements to support the additional weight.

Cool roof technology is a promising way to reduce greenhouse gas emissions and improve the energy efficiency of buildings. As the technology continues to develop, the potential for cool roofs to reduce carbon dioxide emissions will likely increase.

This is an easy way to make big gains in carbon reductions, saving homeowners and businesses money. Something we can all get behind.

Source Happy Eco News

The Five Best Ways for Free Home Cooling with No AC

Posted on July 25, 2023 by dishanth

It’s hot these days. Here are the five common sense ways for home cooling with no AC.

Close your curtains and blinds during the day. This will help to keep the sun’s heat out of your home. If you don’t have curtains or blinds, you can use sheets or towels to cover your windows. Close your curtains and blinds during the day.
Run ceiling fans. Ceiling fans can help to circulate the air in your home, which can help to keep you cool. If you have a ceiling fan, ensure it is set to blow down.
Use fans to create a cross breeze. If you have windows on opposite sides of your home, you can open them to create a cross breeze. This will help to draw the cooler air in from outside and push the hot air out.
Take cool showers or baths. Taking a cool shower or bath can help to lower your body temperature. You can also use a wet towel to cool down your neck and forehead.
Cook outside and unplug devices. Cooking outside on a barbeque, camp stove, RV, or other appliance outside will help keep your house cooler. The heat generated by an oven or a stove can quickly counteract any other efforts you made throughout the day.

Here are some additional tips to keep your home cool without air conditioning:

Ventilate your home at night. If it’s cooler outside than it is inside, open your windows at night to let in the cool air and begin the next day with a nice cool house.
Plant trees around your home. Trees can help to shade your home and keep it cooler in the summer.
Use reflective insulation. Reflective insulation can help to reflect the sun’s heat away from your home.
Seal up any air leaks. Air leaks can let in hot air, so sealing them up is important.

By following these tips, you can keep your home cool without air conditioning and save money on your energy bills.

Source Happy Eco News

Five sustainable solutions to help tackle extreme heat in South Asia

Posted on November 23, 2021November 23, 2021 by dishanth

As the world warms, there is an urgent need to find ways to keep people cool. This year, several deadly records have been set in South Asia: in New Delhi, the highest July temperature in 90 years was recorded, at 43.6 degrees Celsius. In April in Karachi, mercury levels hit 44C — the highest in 74 years.

Last week, the climate analysis coalition Climate Action Tracker published research showing that even if the new pledges made by the world’s governments in the first week of COP26 are achieved, global temperatures would rise by more than 2.4C this century. This coincided with the publication of research showing that with just a 2C global temperature rise, a billion people will be affected by extreme heat stress.

Even at 1.5C of global warming (the aspirational target set by the Paris Agreement), studies have found that deadly heat stress could become common across South Asia. Despite pledges to control greenhouse gas emissions, scientists say the world could reach the 1.5C threshold in a matter of years.

There is therefore a pressing need for sustainable cooling technologies and practices that are both low-carbon and accessible to the poorest people — who are also most at risk of heatwaves. And, crucially, there needs to be grassroots support for the proposed solutions.

“We cannot agree on global multilateral solutions if we don’t have local, appropriate implementation,” said Carlos Alvarado Quesada, president of Costa Rica, speaking in Glasgow on 4 November at an awards ceremony held by Ashden, a UK charity that supports solutions to the problems caused by climate change. “Implementation has to be done locally, respecting women, respecting indigenous communities [and] working together with them.”

This year’s Ashden Awards, attended by The Third Pole, recognised the importance of sustainable cooling. Many of the projects highlighted below are recipients of finance via its Fair Cooling Fund, which aims to scale up “frontline fair cooling solutions”.

1. Empowering women through low-cost solutions

Houses in poor neighbourhoods are usually built from cement, often with plastic covers or tin sheets to keep the rain out. These materials absorb heat, and create hot and stuffy living conditions. As urban populations increase and the impacts of global warming become more apparent, the problems will worsen — with knock-on impacts for sanitation and health. Women are particularly exposed, as their work often takes place within the home.

Mahila Housing Trust (MHT) is a not-for-profit organisation based in Ahmedabad. It works in 10 cities across India to boost communities’ resilience to heat stress. It provides women with advice on how to cool their homes in ways that are easily implemented and affordable: to date, more than 1,600 women have been educated about climate change and how to deal with some of its effects.

The techniques focus on passive cooling methods — preventing heat from building up within people’s homes. One of the quickest and easiest to implement is painting roofs and sun-facing walls with solar-reflective paint, which can reduce indoor temperatures by 4-5C. According to the Global Cool Cities Alliance, when sunlight hits a light-coloured roof, 80 per cent of its energy is reflected, compared with 5 per cent for a dark-coloured roof.

A second easy step MHT advises is to grow potted plants and creepers on roofs, which the charity says can reduce indoor temperatures by 2.5C. Vegetation has been proven to have a cooling effect through shading and evapotranspiration. MHT has helped about 200 houses in Bhopal and Ranchi to do this.

MHT also advises on and helps with renovating roofs. The replacement structures have vents and are made from recycled materials that let more light in without trapping heat. According to MHT, these can reduce temperatures by 6-7C. Finally, the charity trains women on principles for reducing heat stress. For example, said Aneri Nihalani, MHT’s communications officer, considering the orientation of a building during construction can help reduce overheating. Taking these steps can help with the family’s finances as well as their comfort, as they need less electricity to cool their homes.

Since 2014, the Mahila Housing Trust has helped more than 2,000 families to adopt heat-resilient measures. In recognition of its work, MHT won the 2021 Ashden Award for Cooling in Informal Settlements, which was presented at COP26.

2. Geothermal air-conditioning

The temperature on the surface of the Earth fluctuates constantly. But below the Earth’s surface there is little change in temperature. The founders of GeoAirCon, a company in Pakistan, have harnessed this stability to cool homes down.

In a GeoAirCon system, a ‘loop’ of underground pipes filled with fluid is installed. Geothermal heat pumps move heat around the system. During the summer, these pipes draw heated water from the building and move it underground. (In winter, the opposite principle applies to warm the house.)

According to the company, the temperature of the earth about 8-12 feet below the surface in Pakistan ranges from 21-25C. GeoAirCon systems can therefore cool buildings to this range — a comfortable temperature for the human body.

GeoAirCon says geothermal systems are twice as efficient in cooling as the most efficient conventional air-conditioning system. Cooling capacity is influenced heavily by the insulation of a building, M Hassamuddin, chief executive of GeoAirCon, told The Third Pole, so use of passive cooling best practices is also advised.

A system costs US$260-460 to install, and costs significantly less to run than a conventional air-conditioning unit, according to the company. Hassamuddin said that though more suited to houses with outdoor spaces, the technology can be installed in densely populated areas, with an area less than a metre wide required to make the hole for the underground pipes.

So far, GeoAirCon systems have been installed in 12 buildings in Pakistan. GeoAirCon was runner up for the 2021 Ashden Award for Cooling in Informal Settlements.

3. Low-impact cooling systems

In 2015, eight million air conditioners were installed in India. That number is expected to grow by 200-300 million in the next 20 years. But traditional air conditioning is expensive, electricity-intensive and often uses greenhouse gases like HFCs, exacerbating the climate crisis.

CBalance, an Indian consultancy that has also received financial support from Ashden, is working to reduce the reliance on conventional air-conditioning. It promotes passive cooling design and ventilation, fostering cooperation between architects and urban communities through its Fairconditioning programme. Hasan ul Banna Khan, an engineer working on Fairconditioning, told The Third Pole that in most cases a building can maintain a comfortable temperature using just passive design techniques coupled with sustainable cooling systems.

Having reduced the requirement for artificial cooling as much as possible, it also promotes technologies that reduce the energy and greenhouse gas intensity of cooling.

These include:

• Evaporative cooling, which uses evaporated water to cool air. Unlike conventional air conditioning, this does not use refrigeration, and therefore requires a lot less energy. In one building in Pune, this system reduces the need for conventional AC by 40 per cent.

• Radiant or structure cooling, where cool water is circulated through a building. The technology has been used in 73 large buildings in India, including the Indian Institute of Tropical Meteorology in Pune.

• Use of solar power to chill water.

• Air-conditioning units that are more energy-efficient and emit fewer HFCs.

4. Cool roofs programmes

Under the Ahmedabad Heat Action Plan (HAP) in India, a partnership between the municipal corporation, Indian Institute of Public Health and the Natural Resource Defence Council, more than 7,000 low-income households’ roofs have been painted white. It is estimated that such initiatives save an estimated 1,100 lives every year.

On a bigger scale, the Million Cool Roofs Challenge is a US$2 million philanthropic initiative to rapidly scale up the use of solar-reflective roofs as a form of sustainable cooling in developing countries suffering heat stress. Ten teams are awarded grants of US$100,000.

In 2019, one of the finalists was the team from Bangladesh, a country with high humidity levels and where ambient temperatures are already reaching 40C. The Bangladesh team painted the roofs of two factories and 105 other buildings in Dhaka, including a nursery and a school, with average indoor air temperatures falling by more than 7C.

5. Vernacular architecture providing sustainable cooling

Architects and builders can also look to traditional materials, techniques and designs, which have kept occupants cool for centuries. In one project in Rudrapur, north Bangladesh, students and architects worked with local architects and craftsmen to create houses for low-income families. Using mud and bamboo alongside manmade materials, they installed openings for cross-ventilation, insulation made from coconut fibre and glass windows.

Traditional stilt houses, such as those found in Assam, also use passive cooling. The structures enable cross-ventilation and shading. The walls, which are left unplastered, promote natural ventilation. Recently, projects have started to combine traditional models with materials to enhance their resilience to extreme weather.

The importance of policymakers and urban planning for sustainable cooling

As global emissions drive temperatures to new highs, there is an urgent need to roll out these methods and technologies more widely, at the same time as taking urgent action to limit global warming. Both Aneri Nihalani from MHT and GeoAirCon’s M Hassamuddin told The Third Pole that finance is the main obstacle to wider adoption of the solutions their organisations offer.

Hasan ul Banna Khan from the Fairconditioning programme said there is still a lack of awareness of the impacts of conventional air-conditioning, as well as “a dearth of motivated and skilled architects and engineers in the sustainable building design sector”.

Beyond that, urban planners and policymakers need to step in. In Vietnam, the Hanoi City Master Plan 2030 builds the growing need for sustainable urban cooling into the country’s commitment to be net zero by 2050. It aims to prevent heat build-up throughout the city, using ventilation corridors of green and blue space.

As South Asia warms and urbanises, cities will need to put similar heat adaptation and mitigation measures at the heart of their development plans.

This story was published with permission from The Third Pole.

Source Eco Business