Today's KNOWLEDGE Share:Graphene Based wearable garment for the army

Today's KNOWLEDGE Share:

“At the time, Neel was looking for someone to develop a wearable garment for the armed forces using graphene.

In October 2019, Khushboo Patel, an engineering graduate, collaborated with Neel Panchal, co-founder of graphene manufacturing startup LHP Nanotechnologies, to develop a wearable graphene-based garment for the armed forces.

Using Khushboo’s prior experience and Neel’s expertise in graphene manufacturing, they began working on the concept. Graphene’s unique properties, including flexibility and efficient thermal regulation, were essential for the project’s success.

Khushboo and Neel Panchal did not have a manufacturing space to conduct the experiments and thus decided to do so in their home kitchen. It took them close to 1,000 trials to finally achieve what they sought.

After a month of intensive specialised manufacturing processes for several critical components, the duo was ready with the proof of concept of the ‘heated winter jacket’ for Army personnel.

To overcome the challenge of maintaining the temperature, the duo integrated AI with software that would learn the wearer’s personal preferences in different settings within a short period and then begin to adjust to their comfortable temperature.

“The most crucial parameters were the efficiency of the jacket, ensuring a lightweight nature, longer operating time, durability, and flexibility. Every element had to be redesigned to withstand the harsh climes,” he adds.

However, the duo say that every constraint they faced along the way only kept them trying harder and coming up with more ideas.

To Read more about their journey, check out the link https://buff.ly/3OZgeZP

Source:The Better India

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Researchers Found PFAS Indicator in Some Menstrual Products of USA

Researchers have analyzed over 100 period products for fluorinated compounds, an indicator of potentially harmful per- and polyfluoroalkyl substances, or PFAS. Their results show that while PFAS are absent from many products, they might be accidentally or intentionally added to others.

Period products come in a variety of styles- liners, pads, tampons, cups, and underwear, to help people feel comfortable during a menstrual bleed. But their labels don’t usually list the ingredients, so consumers don’t know what’s in their product of choice.

Risk of Negative Health Outcomes with PFAS:

“Of course, you’re concerned for the wearer, but we’re also concerned about the ecological impact because PFAS are forever chemicals” says Graham Peaslee, Ph.D., the principal investigator of the project. “ Once these products are thrown away, they go to landfills and decay, releasing PFAS into groundwater. And we, or later generations, could end up inadvertently ingesting them.”

PFAS are a category of over 12,000 compounds that have stick, stain- and water-resistant properties, which are desirable characteristics for some products. But because these compounds don’t break down easily in the environment or our bodies, they are persistent and bio accumulative, hence the ‘forever chemical’ moniker. Researchers have also linked exposure to PFAS with an increased risk of negative health outcomes, including some cancers and immune suppression.

Currently, there are few regulatory limits on including PFAS in textiles or period products in the U.S. or Europe, and when it comes to personal products like these, people are concerned about what goes into them, says Peaslee, which is why his research team at the University of Notre Dame started testing them for PFAS.

While it’s not known how much PFAS could pass from different materials through the skin, the team has found these compounds in firefighting gear, school uniforms and period underwear. And other researchers have detected PFAS in additional period products, such as tampons and pads. So, Alyssa Wicks, a graduate student in Peaslee’s lab who is presenting at the meeting, wanted to expand the analyses to a larger variety of period products that haven’t been widely tested, including the packaging for single-use tampons and pads, as well as reusable options, such as menstrual cups.

“Our first step was a screening that’s done quickly and simply,” says Wicks. “We determined if these products had organic fluorine as a surrogate for PFAS.” She cut out a small portion of each item and analyzed it in less than three minutes, using particle-induced gamma-ray emission spectroscopy.

Wrappers having Highest Amount of Flourine:

Some pads and period underwear had multiple layers, which were sampled separately. For instance, some of the tested underwear products had as many as 10 layers, though the average was closer to four. Additionally, the researchers measured total fluorine in the single-use product’s wrappers. So far, Wicks has analyzed 123 period products sold in the U.S., 30 of which were different underwear, with this technique. She also plans to analyze similar products sold in Europe.

The results of these analyses suggest that some period products potentially include PFAS, but not all of them. “In general, tampons didn’t seem to contain fluorine,” says Wicks. “Same with menstrual cups and the layers of pads that come in contact with a person’s skin.”

Most surprising to the researchers was the presence of total fluorine in the wrappers for numerous pads and some tampons, as well as the outer layers of some of the period underwear. Some of the highest amounts measured were 1,000 to several thousand parts per million total fluorine. Because of those high concentrations, Wicks hypothesizes that PFAS might be used to keep moisture out of the wrappers so that the items inside remain dry. In addition, she suggests that adding these compounds to the outer layer of the period underwear would keep blood from escaping the inner layers and stop it from spreading onto a person’s clothing.

This initial work has allowed the researchers to home in on which period products likely have PFAS in them. Next, the team will analyze the samples that contained measurable amounts of fluorine specifically for 40 individual PFAS compounds.

In the meantime, the team notes it is interesting that some products tested in the study were actually free of fluorine. “It’s clear that PFAS are not essential,” concludes Peaslee. “Feminine products are essential, but the need for a fluorinated wrapper, or the need for a fluorinated layer, doesn’t seem to be, because plenty of them are made without relying on these compounds.”

Source: ACS Chemistry for Life/spcialchem

Non-destructive testing: Safran Engineering Services banks on its software suite

LEAP engine fan blades, fixed internal structure panels for their nacelles, internal landing gear pistons. these items all have one thing in common: their quality is inspected and assessed using non-destructive testing (NDT), for which Safran Engineering Services has developed the SMV2 software suite. The development prospects are promising.

Non-destructive testing: a technique for the future.

Non-destructive testing (NDT) is a technique used to inspect and assess the quality of materials, components or structures, while preserving their integrity. It uses a variety of methods and technologies to detect defects such as cracks, porosities, inclusions, dimensional variations and other potential imperfections in the materials. Safran uses this type of technology to inspect metal and composite parts, including large-scale components.

The Group therefore called on internal and external expertise to develop high-performance non-destructive testing tools. One of the most ambitious, enabling the inspection of fixed internal nacelle structure panels, is based on an infrared thermography inspection method using a flash and a thermal camera. “This is an innovative method. Others use digital tomography, 2D digital radiography or visual inspection with high-definition digital cameras,” explains Marc Garas, application software service manager at Safran Engineering Services.

Safran Engineering Services has been involved in the research phases of these projects from the outset, and it has developed a software suite, a veritable toolbox that can be adapted to different testing projects.

The SMV2 software suite

This software suite, known as SMV2, has been designed for the Group’s various use cases, from the different acquisition methods – thermography, tomography, radiography and digital cameras – to the geometric specificities of each part and the types of peculiarities to be investigated. The Human-Machine Interfaces (HMIs) have been the subject of extensive ergonomic research to help inspectors in their work.

Integrated into a robotized cell, the software suite performs multiple functions. “In the case of nacelle parts, it communicates with the robotized cell and controls the infra-red camera built into the cell, as well as the flash which heats the surface of the part. It allows images to be analyzed by an operator to detect any defects. It supervises the entire process in real time, and stores information in a database which can then be used by data scientists or production managers,” continues Marc Garas. An inspection report, which is used to validate the part, can then be generated automatically.

Source:www.safran-group.com/jeccomposites

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Today's KNOWLEDGE Share:Petrochemicals Historical timeline- Part 7

Today's KNOWLEDGE Share:

Petrochemicals Historical timeline- Part 7

Early 1950s Polypropylene discoveries were made in different places because of improved knowledge sharing but this led to nine different teams claiming

to have invented it. Patent litigation was finally resolved in 1989. American chemists Paul Hogan and Robert Banks, working for Phillips Petroleum, are generally credited as the inventors.

1955 South Africa started making its own synthetic fuels using the Fischer-Tropsch method because of limited oil imports with the trade sanctions under the apartheid regime.

1960s Work conducted on water conservation for soils in the US led to the development of a resin in the form of an acrylic gel which were then developed into super-absorbent fibres.Commercial production began in Japan in 1978 and in 1980, super-absorbent polymer was used in baby diaper production.

1960s First synthetic oils are developed with Mobil Oil and AMSOIL leading the field. The synthetics contain additives such as polyalphaolefins

derived from olefins. Introduced commercially in the 1970s to the automotive market.

1963 Australian chemists start work on conducting substances for computer screen shields, windows that can exclude sunlight and photographic film.

1965 Kevlar was invented at DuPont as a result of research involving high performance chemical compounds. It is used in bullet-proof vests, underwater cables, space vehicles, brake linings, skis,building materials, parachutes, boats and skis.

Source:World Petroleum Council Guide

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Dow Partners with Mengniu to Launch All-PE Yoghurt Pouch Designed for Recyclability

Dow, a global materials science company, has partnered with Mengniu, a dairy company in China, to launch an all-polyethylene (PE) yogurt pouch designed for recyclability. This innovation strengthens both companies’ commitment to achieving a circular economy in China.

Enables Recycling of Hard-to-Recycle Packaging:

Leveraging the materials science expertise of Dow and the collaboration across the value chain, Mengniu developed its first all-PE yogurt pouch designed for recyclability. Dow's INNATE™ TF-BOPE resins help ensure that packaging maintains its superior appearance and productiveness.

The newly developed all-PE packaging enabled by INNATE™ TF-BOPE resins is a breakthrough for the dairy industry, as it enables traditional hard-to-recycle packaging to be integrated into closed-loop recycling streams through responsible recycling and mechanical recycling technology, providing consumers with more choices of sustainable packaging.

“This partnership with Mengniu is a milestone for both brands to pioneer all-PE dairy packaging designed for recyclability in China. The country’s ambition to work towards Zero-waste Cities has changed how it tackles plastic waste. This collaboration is a significant step in facilitating recyclability and empowering the possibilities for recycled packaging to be transformed into high-value applications through responsible disposal and appropriate recycling process, reducing our industry’s reliance on unrenewable resources. Through our advanced research and development capabilities, we strive to help brand owners like Mengniu to take action and deliver on their sustainability commitments,” said Bambang Candra, Asia Pacific commercial vice president of Dow Packaging and Specialty Plastics.

Mengniu set a goal to achieve 100% technically recyclable packaging by 2025, striving to adopt low-carbon packaging in all product lines. Environmental-friendly manufacturing is an important pillar of Mengniu’s sustainability strategy, and adopting more sustainable packaging is one significant action to fulfil the commitment.

Mengniu's yogurt with this all-PE packaging designed for recyclability was unveiled at the 2023 International Dairy Forum from Aug 4 to Aug 7 in Hohhot, a major city in Northern China, and will be available starting from supermarkets across the city.

Source: Dow/specialchem

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New paint gives extra insulation, saving on energy, costs, and carbon emissions

Researchers show that their newly invented paints, which they produced in a wide array of colors, can reduce the need for both heating and air conditioning in buildings and other spaces, like trains and trucks for refrigerated cargo.

Stanford University scientists have invented a new kind of paint that can keep homes and other buildings cooler in the summer and warmer in the winter, significantly reducing energy use, costs, and greenhouse gas emissions.

Space heating and cooling accounts for about 13 percent of global energy use and about 11 percent of greenhouse gas emissions. The new paints reduced the energy used for heating by about 36 percent in experiments using artificial, cold environments, according to a study published today in the Proceedings of the National Academy of Sciences. They reduced the energy needed for cooling by almost 21 percent in artificial warm conditions. In simulations of a typical mid-rise apartment building in different climate zones across the United States with the new paint on exterior walls and roofs, total heating, ventilation, and air conditioning energy use declined 7.4 percent over the course of a year.

“Energy and emissions from heating are forecast to continue to fall due to energy efficiency gains, but air conditioning use is rising, especially in developing economies in a warming world,” said the study’s senior author, Yi Cui, professor of materials science and engineering, of energy science and engineering, and of photon science at SLAC National Accelerator Laboratory.

“For both heating and air conditioning we must reduce energy and emissions globally to meet our zero-emissions goals,” said Cui, who directs the Precourt Institute for Energy and the Sustainability Accelerator, both within the Stanford Doerr School of Sustainability. “How to reduce heat exchange between human living and work spaces and their surroundings is getting more attention, and new materials for enhanced insulation – like low-emissivity films for windows – are in demand.”

A colorful solution

Current low-emissivity paints usually have a metallic silver or gray color, the aesthetics of which limit their use. The newly invented paints have two layers applied separately: an infrared reflective bottom layer using aluminum flakes and an ultrathin, infrared transparent upper layer using inorganic nanoparticles that comes in a wide range of colors. The infrared spectrum of sunlight causes 49 percent of natural heating of the planet when it is absorbed by surfaces.

For keeping heat out, the paint can be applied to exterior walls and roofs. Most of this infrared light passes through the color layer of the new paints, reflects off the lower layer, and passes back out as light, not being absorbed by the building materials as heat. To keep heat inside, the paints are applied to interior walls where, again, the lower layer reflects the infrared waves that transfer energy across space and are invisible to the human eye.

Specifically, up to about 80 percent of high mid-infrared light is reflected by the paints, doing most of the work of keeping heat inside during cold weather and outside during hot weather. The color layer also reflects some near-infrared light, enhancing the reduction in air conditioning. The research team tested their paints in white, blue, red, yellow, green, orange, purple, and dark gray. They were 10 times better than conventional paints in the same colors at reflecting high mid-infrared light, the researchers found.

Not just for buildings

The paints can be applied beyond buildings to improve energy efficiencies elsewhere. For example, they could cover trucks and train cars used for refrigerated transportation, in which cooling costs can take up to half the transportation budget.

“Both layers can be sprayed onto assorted surfaces of various shapes and materials providing an extra thermal barrier in many different situations,” said Yucan Peng, co-lead author of the study, who completed her PhD in materials science at Stanford in 2020 and is now a postdoctoral scholar in Stanford’s Geballe Laboratory for Advanced Materials.

The researchers also evaluated how practical their paints would be in various situations. Both layers are water-repellant, which should enhance stability in humid environments. Painted surfaces can be cleaned easily with wet cloth or water flushing, the researchers report. Furthermore, the paints’ performance and aesthetics were not diminished after continuous exposure for one week to high temperature (176 degrees Fahrenheit), low temperature (-320.5 degrees Fahrenheit), as well as high acidic and low acidic environments. The paint actually increased the use of air conditioning slightly in some U.S. cities, but no location showed an increased total HVAC load.

“Our team continues to work on refining the paint formulations for practical applications,” said the study’s other co-lead author, Jian-Cheng Lai, a postdoctoral scholar advised by Zhenan Bao, professor of chemical engineering. “For example, water-based solutions would be more environmentally friendly than the organic solvents we used. That could facilitate the commercialization of the paints.”

Source:Stanford News

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Today's KNOWLEDGE Share:GFRP CLADDING

Today's KNOWLEDGE Share:

Curve Works' black GFRP cladding is still looking brand new 4 years after installation!

The attached photo, taken a few weeks ago, is of a GFRP bridge installed in Norway in 2019.

This bridge is a fantastic example of sustainability. Not much material has been used; it is lightweight (installed in 1 piece, lifted from a truck!) and the composite structure lasts more than 100 years without maintenance (no corrosion and no rot)!

The 120 sqm sandwich cladding, for which recycled PET-core was used weighs only 1000 kg.

GFRP Cladding: Manufactured by Curve Works

GFRP Bridge: Engineered & Manufactured by FiberCore Europe

Client: Module Solutions & Systems AS.

Source:Francois Geuskens Curve Works B.V

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