Cooling wood: Engineers make strong, sustainable solution for passive cooling

Consider the possibility that the wood individuals’ home was made of could save their electricity bill. In the race to save energy, utilizing a passive cooling strategy that requires no electricity and is incorporated appropriate with their home could save even chilly areas of the US some money. Presently, specialists at the University of Maryland and the University of Colorado have saddled nature’s nanotechnology to help solve the issue of finding a passive way for buildings to dump heat that is sustainable and strong.

Wood solves the issue—it is now utilized as a building material, and is renewable and sustainable. Utilizing small structures found in wood—cellulose nanofibers and the natural chambers that develop to pass water and nutrients up and down inside a living tree—that specially processed wood has optical properties that transmit heat away. The consequences of this study were published May 9 in the journal Science.

“This work has greatly extended the use of wood towards high performance energy efficient applications and provided a sustainable route to combat the energy crisis,” said Northeast Forestry University Professor Jian Li, a member of Chinese Academy of Engineering, who is not associated with the research.

At the University of Maryland, Liangbing Hu, co-first authors Tian Li and Shuaiming He and others in the department of materials science have been working with wood for many years. Hu’s group has created a range of emerging wood nanotechnologies, including a transparent wood, minimal effort wood batteries, super strong wood, super thermal insulating wood, and a wood-based water purifier.

“This is another major advancement in wood nanotechnologies that Hu group at University of Maryland achieved: cooling wood that is made of solely wood—that is, no any other component such as polymers—can cool your house as a green building material,” said Dr. Hu.

The group at Boulder, led by Prof. Xiaobo Yin and including co-first author Yao Zhai, both of the of the department of mechanical engineering and the program of materials science at the University of Colorado in Boulder, have been dealing with materials for radiative cooling, including thin films and paints.

“When applied to building, this game-changing structural material cools without the input of electricity or water,” Dr. Zhai said.

By expelling the lignin, the part of the wood that makes it brown and strong, the UMD scientists made a pale wood made of cellulose nanofibers. They then compressed the wood to restore its strength. To make it water repellent, they included a super hydrophobic compound that secures the wood. The result: a splendid white building material that could be utilized for roofs to push away warmth from inside the building.

They took the cooling wood out into the perfect testing condition of a farm in Arizona where the climate is in every case warm and sunny, with low winds. There, they tested the cooling wood and found that it stayed, on average, five or six degrees F cooler than the ambient air temperature—even at the hottest part of the day, the cooling wood was chillier than air. It remained on average 12 degrees cooler than natural wood, which heats up additional within the presence of sunlight.

“The processed wood uses the cold universe as heat sink and release thermal energy into it via atmospheric transparency window. It is a sustainable material for sustainable energy to combat global warming” said Dr. Li.

The mechanical strength per weight of this wood is likewise stronger than steel, which makes on it a great choice for building materials. It is ten times stronger than natural wood and beats steel’s strength, reaching 334 MPa·cm3/g (compared to 110 MPa·cm3/g for steel). It likewise harms less effectively (scratch test) and can manage more weight (pressure test) than natural wood.

Different associates incorporate Jelena Srebric’s group at the University of Maryland, College Park; Ronggui Yang’s group at the University of Colorado, Boulder; and Ashlie Martini’s group at the University of California Merced.

To see how much energy the wood saves, they calculated how much heat is used by typical apartment buildings in cities across the US in all climate zones. Hot cities like Phoenix and Honolulu would save the most energy, particularly if older buildings had their siding and roofs replaced with cooling wood. Buildings across the US that were built after 2004, or at present, would save on average 20% of cooling costs.

“Prof. Hu and collaborators show yet another use of wood that is not only structurally strong but useful as active component for energy management. It is interesting that the same material that releases heat upon combustion can be used for cooling, offering new opportunities in green buildings,” said Orlando Rojas, a professor in the department of Bioproducts and Biosystems at Aalto University, Finland.