Bio-based membranes for energy storage
CategoriesSustainable News

Bio-based membranes for energy storage

Spotted: While the transition to renewable energy is picking up pace all the time, there are still several technological challenges facing those looking to build a fully sustainable future. One of these is the need for a more efficient way to store energy. Many renewable sources, such as wind and solar power, are intermittent, and it is vital to find ways to store this energy when it is not needed. Redox flow batteries are among the most efficient energy storage technologies. Now, Swedish startup Cellfion is working to make redox flow batteries even more efficient with a unique, bio-based membrane.

Redox flow batteries are a type of electrochemical cell where dissolved chemicals are pumped through the system on separate sides of a membrane, leading to ion transfer and the flow of electric current through an external circuit. Cellfion has developed a novel ion-selective membrane derived from cellulose. The cellulose fibres are extracted from wood and fabricated into membrane sheets that are then used as components in energy storage and conversion devices.

The bio-based membranes have several advantages over traditional membranes, which are often made from chemical polymers such as perfluorosulfonic acid. Cellfion’s cellulose membranes are non-toxic and decomposable but retain the high ion selectivity and conductivity typical of traditional membranes. In addition, at the end of their life, they can be incinerated without releasing any toxins into the environment, unlike traditional membranes.

According to Liam Hardey, Cellfion CEO, “To the best of our knowledge and extensive research, we are the first company working towards the commercialisation of bio-based membranes with no toxic substances at all”. He adds this is vital because, “If the clean energy industry is to become sustainable, we need to ensure that the materials we are using are also truly sustainable.”

More efficient battery storage is a key part of the transition to renewable energy. This is why Springwise is seeing an increase in new, more sustainable battery technologies. Innovations in this space include a green battery made from abundant and locally-sourced components and batteries that dissolve in water.

Written By: Lisa Magloff

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Structural Membranes: Exploring ETFE and PTFE Synthetic Polymers in Architecture
CategoriesArchitecture

Structural Membranes: Exploring ETFE and PTFE Synthetic Polymers in Architecture

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Modern chemistry made mass-producing polymers possible and continues to facilitate the use of synthetic polymers in architecture. Membranes are one of the most visible forms of polymers in design and construction. Waterproofed membranes add a layer to the building’s envelope that both prevents damp walls and helps control the humidity inside. This approach to structure and envelope, which has gradually become popular since the late 20th century, is an especially good choice for public projects with large span roofs. For example, the Millennium Dome by RSHP, which has been badly damaged by the extraordinarily destructive storm Eunice, is a dome structure with a skin of PTFE coated glass fabric that has an astonishing diameter of 1, 200 feet (365 m) and a height of 165 feet (50 m).

A roof formed by a single layer of membrane is significantly thinner than structures built from traditional materials such as timber and bricks, while it is possible to be as strong as steel, depending on the material. The resulting structure, therefore, preserves lightness both structurally and visually. Meanwhile, they are strong enough to stand against the weather and good at self-cleaning. This article looks at two predominant synthetic polymers — both plastics that are categorized as textiles. PTFE, polytetrafluoroethylene, is constructed from carbon and fluorine atoms. Meanwhile, ETFE, ethylene tetrafluoroethylene, is built from carbon, fluorine and hydrogen. While the former is more fire-resistant, the latter performs better under tensile pressure.

Sogokagu Design Lab_exterior

Polymers are also applied as hard materials, the Sogokagu Design Lab by Kengo Kuma and Associates has a ETFE façade.

So far, membranes sound ideal for large-span structures. However, the performance of the material heavily depends on its structural integrity. If just one part of the piece breaks, normally, if the type of membrane used is fabric-based like PTFE, the replacement of a whole piece will be required. Therefore, the maintenance and repair of membrane structures can be quite costly, which should be considered when choosing the material.

There is also a wide range of sheet materials that can be considered as membranes. Some are woven fabrics coated with polymers, some come directly as foils/films. ETFE is one of the most popular materials for membrane structures as it becomes a film that is highly flexible to fit onto the skeleton of different shapes. It is also transparent enough to let lights travel through, either allowing daylight into the space to utilize natural light or creating a luminous, performative visual of the building at night by lighting it from the inside. Moreover, the material is highly recyclable — although not biodegradable. Still, already-used ETFE can be reprocessed into new ETFE materials.

water cube_night_exteriorwater cube_day_interiorDesigned by PTW Architects, the National Swimming Centre in Beijing, also called Water Cube, has an iconic “bubbling” façade made of ETFE. To achieve this appearance, ETFE films are first welded together, then installed onto the steel frames and lastly filled with inert gases using the piped embedded in the steel frames to form cushions. The swimming pool is lit by natural light during the daytime and very little artificial lighting is needed, thanks to the transparency of ETFE.

Solar energy is let through the envelope as well and heats the space, the water and the concrete floor structure. During the night, the concrete floor of high thermal mass gives out heat that is stored during the daytime, saving energy on air-conditioning. As each cushion is independent of the others, a broken cushion can be quickly repaired by welding a supplementing patch of ETFE onto it or be simply replaced with a new cushion to secure the integrity of the envelope.

Functioning similarly to double- and triple-glazing, the gas-filled cushions are good insulators for noise and heat as well. The insulating function of ETFE cushions has been already proved in the Eden project (2001), where ETFE cushions help control climates in enormous greenhouses.

selgascano serpentine_day_interiorWhile Water Cube employs ETFE cushions for their environmental performance, the Serpentine Pavilion 2015 designed by SelgasCano plays with the material’s transparency. Using colored and color-diffusing ETFE films, joined by colored ribbons, the design team created a surreally colorful spatial experience. ETFE films and ribbons of different shades are attached to the steel skeleton, forming a double skin system where shades overlay building new shades and forms penetrate forming dreamy shadows. The lightness of the material allowed all skin sections to be installed by hand.

PTFE membranes, on the other hand, are normally manufactured by coating PTFE onto glass fabrics, which makes them highly resistant to cracks under stretching and more scratch-resistant than ETFE. The strength of the material allows the formation of dramatic free form structures. While PTFE membrane facilitates natural lighting as ETFE does, it can further filter UV light thus preventing possible damages to furniture caused by long-term UV light exposure. Similar to ETFE, it is also anti-corrosion and easy to clean.

Feuerstein-Arena Schierke_dayFeuerstein-Arena Schierk_nighteThe Ice Stadium Schierker Feuerstein-Arena designed by GRAFT stands out in the competition to renovate the stadium for its unique roof. The roof of over 29,000 square feet (2, 700 sq. m) spans across the ice rink, meeting the ground at its two ends. The lightweight yet strong PTFE membrane rests on a net of steel ropes which is then fixed to the outer steel frame. The structure bears wind, rain and snow and sheltered the stadium from direct sunlight by diffusing it. During the night, the reflectivity of the material spreads lights across the whole roof, multiplying the artificial lighting.

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