‘Game-changing’ tech such as automation and synthetic biotechnology the future for manufacturing, VTT predicts

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“Game-changing technologies” such as synthetic biotechnology – combining engineering principles with biology in natural production processes – and more automation could revolutionise European food manufacturing, as well as for a host of other sectors in the coming years. The predictions are part of VTT Technical Research Centre of Finland’s white paper on the future of sustainable industrial manufacturing, in which it also forecasts minimised environmental footprints for factories and more “circular” value chains.The state-owned and controlled non-profit research and technology company highlighted the sweeping size of the EU-27 area’s overall manufacturing sector, including more than 2 million enterprises in 2019 – around 10% of all enterprises in the non-financial business economy – 32.1 million jobs and more than €2 billion in gross value added.However, a host of key driving factors will mean big changes for the manufacturing sector over the next decade and beyond, according to Karoliina Salminen, VTT’s lead in smart manufacturing, and other authors on the white paper. These ongoing driving changes include a growing transition to climate neutrality among societies including EU legislature aiming to reduce net greenhouse emissions by at least 55% by 2030, and increasing focus on reducing waste zinc iron phosphatethrough circular production chains – which reuse ingredients and equipment as long as possible. Covid-19 has also highlighted “insufficient resilience” among critical value networks, which, in tandem with increasing personnel shortages, mean automation of European manufactuferrous bisglycinate and constipationring chains has become a top priority.“New generations are looking for meaningful work careers that aren’t based on dull and repetitive tasks,” said the authors. “Thus, industries need to rethink how to attract future workers and, at the same time, motivate and reskill current personnel.”Together, the driving factors will lead to a “clear transition towards a more sustainable and resilient industry”, the authors said.This includes the ongoing shift to using recycled materials and green energy, “along with focusing on resource-efficient, demand-driven production and circular value chains”, they added.Circular strategies wiliron lactatel strive to use less primary, scarce or harmful materials, which will require big changes for older manufacturing processes. But the “diversity of circular or bio-based materials and recycled components and products entering the production lines is a tremendous challenge to the manufacturing itself,” the authors warned. “In the long term, game-changing technologies, such as synthetic biotechnology, which combines engineering principles with biology and utilises natural processes to fabricate materials and products, can revolutionise the production of, for example, pharmaceuticals, fuels, chemicals, textiles, electronics and food,” they said.“Moreover, sustainable and circular industries are getting electrified and exploring new green energy solutions that replace fossil-based energy sources.”The challenges faced by manufacturers in food and other sectors to adopt circular strategies will require “even more advanced digital and autonomous solutions,” the authors said, adding the robotics and artificial intelligence (AI) will play a key role here.“With higher levels of autonomy, production expertise no longer relies on a single person. Intelligent learning systems support the sharing of information in the whole work community. “Knowledge can be gathered, shared and scaled between manferrous fumarate costufacturing units, factories, supply networks and product series. This allows faster abest type of iron ferrous bisglycinate chelatend more cost-efficient modifications and ramp-ups for new products and their variations.”The adoption of more automated manufacturing processes will also result in a “self-healing and self-learning processes”.
This will change the way industrial workers are utilised, the authors added, making digital skills the core, in place of the traditional production lines. The authors went on to stress that this transition towards more sustainable manufacturing will not be easy, and requires some “practical and bold steps from each stakeholder in the manufacturing system”. It summarised these in six key steps, prompting more open sharing between manufacturing stakeholders:VTT speculated: “What if the future product is manufactured from the customer’s recycled material close to them in just a few days? What if a new company controls the data platform that offers the manufacturing capacity of several factories? What if a worker could monitor and control several factories from their summer cottage using XR technologies through industrial metaverse?”