Scottish Don & Low orders nonwovens plant from Oerlikon Neumag
Following the recent investment by Scottish company Don & Low, another leading western European nonwoven manufacturer has invested in an Oerlikon Neumag meltblown plant. The now signed contract comprises a system for the production of nonwovens made from polyolefins and other raw materials. The commercial production launch has been scheduled for the first half of 2017
This investment marks the second nonwoven plant that Oerlikon Neumag has been able to place with leading European meltblown nonwoven manufacturers in a period of just a few months. “The successes of the last few years demonstrate that we have not only secured our pioneering role with the constant further development of our market-leading meltblown technology, we have actually managed to expand it”, explains Axel Becker, Sales Director Nonwoven at Oerlikon Neumag. “With our technology, our customers develop trailblazing products, hence strengthening their position within the global market and developing the products of the future with this technology.”
Meltblown technology as stand-alone or as upgrade solutions for even better product quality. The market for meltblown nonwovens is expanding by an average of 6 % per annum. The Oerlikon Neumag meltblown technology enables the cost-efficient manufacture of high-end meltblown and SMS (spunbond-meltblown-spunbond) products. Stand-alone mono-component and bi-component meltblown plants produce nonwovens for a whole range of filtration, insulation and sorption applications. As ‘plug & produce’ installations in already existing and new third-party composite systems, the meltblown technology is deployed for a whole range of medical and hygiene products. This solution permits the cost- efficient upgrading of new or existing spunbond systems and offers nonwoven manufacturers access to markets with especially high quality requirements. In addition to standard polymers, such as polyester and polypropylene, for example, promising polymers such as fluoropolymers can also be optimally pro- cessed.