THE BUILDING PRODUCT E-BULLETIN

NEWSLETTER SIGNUP
This article appears in
Sector- Education ( 27 June 2019 )

27 June 2019

Hunter Douglas Architectural presents new range of wooden ceiling and wall systems with nano-perforations
Hunter Douglas

Suite 2 Newton House, Northampton Science Park, Kings Park Road, Moulton Park Industrial Estate, Northampton, United Kingdom , NN3 6LG

T: +44 (0)1604 648229
E: info@hunterdouglas.co.uk
W: https://www.hunterdouglasarchitectural.eu/en-GB/home/index.jsp

Request Literature

Hunter Douglas Architectural presents new range of wooden ceiling and wall systems with nano-perforations

Hunter Douglas Architectural has launched an innovative range of wooden ceiling and wall systems with nano-perforations that provide excellent acoustics without compromising on the aesthetic quality.

The wood veneer panels contain countless microscopic perforations, which at 0.5mm diameter are hardly visible to the naked eye and have superior absorptions qualities.

Chris Wielenga, Business Manager Wood at Hunter Douglas Architectural, said: “The nano-perforations in the wood veneer are so tiny that they are invisible to the naked eye from only a short distance, unlike the usual perforations that have a larger diameter of around 5-10mm.“

In testing, the nano-perforated panels were shown to have a sound absorption til αw: 0.95, NRC: 0.90 and SAA: 0.90. Standard perforations generally achieve about αw: 0.75, NRC: 0.75 and SAA 0.70.”

The nano-perforated panels have been developed by Hunter Douglas Architectural in response to growing demands from architects for wall and ceiling solutions that are both aesthetically pleasing and acoustically effective.

“We are seeing more interest in perforated panels due to their excellent acoustic properties,” explained Chris. “Our nano-perforations offer a virtually invisible alternative, and many architects highly appreciate that.”

The nano-perforated acoustic panels comprise fire-retardant 16mm MDF, a black acoustic membrane and a top layer of 0.5mm wood veneer. Microscopic perforations with a diameter of 0.5mm are punched into the top layer, while the MDF receives larger perforations up to 12mm in diameter.

“The microscopic perforations mean that the top layer appears non-perforated, while the larger perforations are concealed behind the veneer in the MDF,” said Chris. “This allows us to increase the size of the perforations in the MDF, improving the sound-absorbing capabilities.

”The punching method differs from commonly employed perforation techniques, too. The usual method is to create perforations using needles, but the displaced wood tends to move back, which affects absorption. Punching removes the wood completely.

The new wall and ceiling panels are available in more than 40 types of wood veneer and they are available in various standard sizes (600mm x 600mm, 1200mm x 600mm, 1800mm x 600mm, with a maximum length of 2780mm for wall panels) or in custom sizes on request.

A range of finishes, in addition to the standard UV lacquer, includes various levels of glossiness and a pigmented finish such as whitewash, while the panel joints can be covered, semi-covered or open.

“That is unheard of among competitors,” said Chris. “Moreover, we buy our own veneer and then create large sheets inhouse, allowing us to include the architects’ input in determining the quality and appearance – the size of the grain and the number of knots, for example. Most suppliers purchase pre-veneered boards, eliminating that option.

”The nano-perforated panels are fire retardant – B-s2, d0 according to EN 13501-1- and sustainable. High-grade veneer is produced from the best part of the tree trunk and is used sparingly. The panels can also be recycled, providing raw materials for new panels.

Ceiling panels are mounted in a T-24 grid, while wall panels are attached to a frame with special clips. All systems offer full access to the plenum after installation, as the panels can be individually removed.

The new range of ceiling and wall systems with nano-perforations is available now.

View Previous Article

View Next Article