Converting Sugar Into Climate-Friendly Plastic - Technology Org | By The Digital Insider


Sugar extracted from corn, sugar beet, and straw is the raw material for future plastic production. Danish company Topsoe is developing a new technology that will reduce the carbon footprint of plastic within a few years.


We need new sustainable and biodegradable alternatives to common plastics.

We need new sustainable and biodegradable alternatives to common plastics. Image credit: everdrop GmbH via Unsplash, free license





















Secret of the technology


The reactor used for the sugar cracking heats the sugar solution to 500-600 degrees in less than one second. And speed is paramount. Heating the sugar more slowly leads to the formation of caramel. And caramel should be avoided at all costs, as the sticky stuff clogs up the reactor—in addition to which the caramel can never be converted into the desired substance of glycolaldehyde.


The secret behind the technology is a so-called fluid bed process. A ceramic powder with a temperature of 500-600 degrees is constantly sprayed into the reactor chamber. The powder is lifted into the reactor by a gaseous sugar solution, which is blown in. This ‘sugar gas’ stream causes the ceramic powder to behave like a liquid. Known as fluidization, the process creates good and even contact between the sugar solution and the ceramic powder. This ensures efficient and extremely fast heating of the sugar to achieve the desired cracking to glycolaldehyde.


Cold reactor


Where the sugar solution is blown over the hot powder is a very critical point in the process, says Anker Degn Jensen.


In order to better study this critical process, DTU Chemical Engineering has built a modified version of the reactor which runs in cold conditions. All parts of this reactor are made from transparent plastic, so you can see into the reactor itself. And the solid substance—the ceramic powder—is circulated at room temperature rather than 500-600 degrees.


“By observing powder’s circulation in the reactor while following the correlation between the powder concentration at different points in the set-up as a function of the amount of gas supplied, we have gained a much better understanding of the process,” explains the professor. 


This study was carried out as a postdoc project in collaboration with the DTU Chemical Engineering workshop that built the reactor. In addition, two PhD studies have been carried out, which have focused on chemical reactions using different powder types and on computer calculation of the processes that take place inside the reactor, respectively 


In the current phase of the project, DTU is looking at sugar cracking in more detail. A postdoc study is testing various materials for use as powder in the reactor to analyse whether it is possible for the process to take place at lower temperatures. 


Long in the making


The development of the new technology has been underway for a long time. It started out in 2010 with the construction of a small laboratory-scale test reactor at Topsoe as part of a PhD project. The results were promising, and in 2017, Topsoe, together with DTU, received a grant of DKK 30 million from Innovation Fund Denmark to scale up the process by building a pilot plant for the production of ethylene glycol. The pilot plant can process about 50 kg of sugar mass an hour. A commercial production facility must be scaled up at least 500 times.


In 2021, Topsoe, together with DTU, Nordic Sugar A/S, and the University of Western Ontario, received an additional DKK 18.6 million from Innovation Fund Denmark to experiment with the reactor and the process itself to optimize production.


The ultimate goal for Topsoe is to demonstrate that the process from sugar to ethylene glycol can be scaled up to actual industrial production. Esben Taarning is both optimistic and excited.


“We hope the first facility can start up in 2026. It would be amazing,” he says.


And the buyer is waiting in the wings. A joint venture between the world’s largest bioplastics manufacturer, Braskem, and Japanese industrial conglomerate Sojitz is keen to buy a licence to build the first commercial facility once the technology is in place.


It will be a huge market to enter. Global production of ethylene glycol stands at 30 million tonnes annually, and the associated carbon footprint is significant. With the new sugar-based technology, Esben Taarning expects to be able to reduce the carbon load by 50 per cent compared to the current fossil load.


Source: DTU










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