Closing the loop on plastics circularity can help solve the massive plastics waste issue facing the world today, said Kevin Quast, the Global Business Lead for Plastics Circularity at Honeywell. Honeywell UOP’s UpCycle Process Technology is helping to do precisely that.
Introduced in 2021, Honeywell’s Upcycle Process Technology is an advanced recycling process based on pyrolysis, a technology that, as the world’s largest process licencing organisation, Honeywell has used for decades. “Pyrolysis is a core competence for us,” said Kevin Quast, the Global Business Lead for Plastics Circularity at Honeywell. “We've now gone above and beyond just pyrolysis within oil and gas. Advanced recycling fits into our strategy as an organisation as we help our customers transform and become more sustainable in their operations.”
Honeywell's UpCycle Process Technology was created within Honeywell's Sustainable Technology Solutions (STS) group, which is part of Honeywell UOP. The company’s deep knowledge of the pyrolysis process spurred the development of the new technology. The company looked at a variety of different business opportunities from an environmental or sustainability perspective, said Quast, and plastics circularity came out as one of the most promising. It is one of a number of areas related to circularity, sustainability, and environmental improvement, including clean hydrogen, carbon sequestration, renewable fuels, and even bioplastics, in which Honeywell is active.
Legislation is a major driver
Plastics circularity is an area where considerable gains remain to be made. The past years have seen vast changes in attitudes towards sustainability within the chemical and plastics industry. In the case of plastics recycling, in particular, the pace of change has been heavily influenced by the legislative mandates and targets that have been introduced, ‘especially in Europe’, noted Quast.
These mandates have led to pledges and commitments being made by consumer goods companies aimed at meeting or exceeding the legislative recycling targets. These companies have been joined by others in the industry, including petrochemical corporations, a main customer group for Honeywell UOP, that are undertaking more sustainable and environmentally responsible activities.
“In other words, the mandates not only changed the attitudes within the industry, but it also got companies to truly commit to making a difference, by reducing their carbon footprint, as well as by producing and using recycled content in new products.”
Meanwhile, it has become evident that the various commitments and pledges made by the industry in relation to recycling, may not be met at the current rate and capacity development of the recycling industry. Mechanical recycling alone, said Quast, is not enough.
“You're going to deploy mechanical as much as you possibly can; it's more inexpensive, and it's easier to implement. But the main problem with mechanical recycling is that only certain types of materials can actually be mechanically recycled. Contaminated flexible waste packaging, multi-layered materials used in frozen food bag packaging, for example, and films and pouches cannot be mechanically recycled. Even when it comes to aseptic TetraPak containers, which are made from paper, plastic and metal, we see that the paper and the metal are separated and recycled, but not the plastic,” he explained. “So, when it comes to advanced recycling, I am obviously not talking about the kind of rigid containers and packaging that can be easily sorted, washed and cost effectively mechanically recycled; that should be very clear.”
However, in cases where mechanical recycling falls short, advanced recycling can provide a solution. The technology can process hard-to-recycle, sometimes highly contaminated plastic waste, turning this into a feedstock which can ultimately be used to create virgin-quality plastics suitable for sensitive food contact or medical applications.
“We saw that this was a way for us to complement mechanical recycling, increase the amount of waste plastic actually being recycled and returned to circulation,” said Quast.
‘It’s not a competition’
For the process to become economically viable, a constant supply of feedstock must be secured. To that end, Honeywell has entered into several non-binding agreements with waste management companies that are active in the waste/ waste treatment and or waste collection/waste trading industries: companies with access to and knowledge of the waste feed.
“In the US, after being picked up, almost all household waste is taken to a MRF – a material recovery facility – where it is sorted. Here’s where a lot of the recyclable waste is sorted out that then goes to be mechanically recycled. It's the rest, the plastics that don’t get sorted out from organics and other waste that we are targeting,” Quast explained.
Globally, however, the emergence of advanced recycling and its need for feedstock has caused disquiet among mechanical recyclers, particularly in countries with advanced mechanical systems and infrastructure in place. Their concerns that the technology will encroach on the feedstock supply are understandable but unnecessary and are something advanced recyclers must work to allay.
“It's an education point. We, as an industry – including waste management companies, the petrochemical industry, the technology providers—we, as players within the space - need to work together and educate one another that mechanical recycling and advanced recycling are complementary. We are not in competition,” he clarified.
He also noted that, with the price point for the sorted plastic going to the mechanical recyclers, it made no sense for this to be processed chemically. Only in areas where there are no good sortation facilities will material of that quality end up being chemically processed, or in cases where the material has already been through a number of recycling cycles and is too degraded to undergo another.
“In general, we haven’t reached that tipping point yet in the industry,” said Quast. “At some point, we might be able to take material that can no longer be mechanically recycled and, instead of sending it to landfill or incinerating it, process it through our Upcycle technology. We could break it back down to the base chemical level to create new feedstock for new plastic.”