Post by account_disabled on Feb 20, 2024 5:46:15 GMT
A typical skyscraper has a huge carbon footprint, both embedded in the production of materials like concrete and steel, as well as the energy used to keep it running. But if this new conceptual 105-story skyscraper is built, it could operate with essentially no carbon footprint. The prototype is a way of saying to the world: 'look, we can make buildings zero carbon.' And not just saying it's zero carbon by buying offsets from a forestry company or buying electricity from a wind farm 20 miles away, but actually on site, in situ, zero carbon. Craig Applegath, founding principal of Dialog, the Toronto-based architecture firm. According to Fast Company , solar panels built into the building's walls (along with batteries) are designed to cover about a quarter of the electricity used. A cogeneration plant in the building provides the rest of the energy, using waste heat from the system for both heating and cooling. The plant runs on natural gas, the emissions are introduced into a bioreactor so that they do not escape into the atmosphere. However, it is not a permanent solution, because although it eliminates emissions in the building, it does not get rid of emissions that occur during the production of natural gas, such as leaks of methane, a potent greenhouse gas.
Still, the same design could potentially be used with renewable natural gas made from methane captured in landfills or on farms. And it is a way to significantly reduce total life cycle emissions. (Moving to fully electrified buildings, which run on renewable energy, is another.) The use of wood The carbon embedded in building materials – all the emissions from the energy and chemical processes of manufacturing Europe Cell Phone Number List such as steel – is also dramatically reduced by design, from around 75,000 tonnes of CO2 in the same building if it was traditionally built with 40,000. tons. That's almost a 50% reduction. The key is to incorporate as much wood as possible into the design. The use of wood in tall buildings is becoming increasingly common as a way to make buildings more sustainable. Wood, a material used to make posts, beams and structural panels with layers of wood, can compete with steel and concrete in strength and weight. And because trees absorb CO2 as they grow, wood can not only reduce emissions, it helps store carbon for as long as the building stands. It is critical that the wood be harvested the correct way: If it's harvested in a way that's sustainable, in other words, if it's harvested selectively, in a way that actually encourages other trees around it to open up and grow, it's going to do a positive job of removing carbon. Unlike if it is cut down. That's bad. "It's worse than using steel or concrete." (Logging releases carbon into the soil, which stores even more carbon than trees.
Developers are racing to build ever-taller wooden buildings. One completed in Norway in 2019 is 18 stories high. But the material is more difficult to use for taller buildings. The higher you are with the wood, the more wood you have to have, because wood is not very good for compression. It's not good to be tall. It is not efficient. What happens is that you automatically price yourself out of the market, compared to steel or concrete. Applegath. As an alternative, the architects propose using a hybrid design that combines wood with concrete and steel. Floor systems, which make up about 70% of a skyscraper's construction material, are primarily made of mass timber. The concrete core and exterior steel are like a typical building. Designers estimate that the building, which would include more than 36,000 cubic meters of wood, could sequester at least 36,000 metric tons of CO2, almost as much as taking 8,000 cars off the streets for a year. Over time, the building's total footprint should be able to decrease even further, as the steel and concrete industries begin to reduce their own carbon footprints. One of the important side benefits of mass timber becoming a sought-after building material is that both the concrete and steel industries are now stepping up their efforts to find ways to reduce their carbon footprint. Concrete companies are starting to incorporate captured CO2 into their products. New technology is making it possible for heavy industrial processes, such as steel manufacturing, to be powered by solar energy. And architects are racing to keep finding the best solutions. As an architect, one of my biggest challenges and concerns is how we are going to reduce the amount of CO2 we are producing, and also how we are going to remove some of the CO2 from the atmosphere.