Inspired by Marcelo Coehlo’s paper speaker and Vincent Leclerc’s Accouphene textile speaker, these paper and are made by running 5-9V amplified sound signal through a very conductive coil in close proximity to a magnet. Unlike most speakers that have the wire coil wrapped cylindrically and placed around the magnet, here the coil is in the plane and directly adhered to the membrane that moves the air creating sound.
Also see: etched, carved and engraved , plated
Vinylcut copper coil
Painted silver coil
Screen-printed silver coil
Video of thermochromic and liquid crystal inks affected by the heat from speaker coils
The coils can be made from a variety of conductive materials. Copper tape,tape, conductive fabric and stainless steel thread work really well. does not work as well (yet!) in comparison. The coil can be one sided or two sided. A continuous spiral gives better results than one that backs up on itself.
The coils can be fused to a variety of membrane materials such as paper, vellum, veneer, fabric, transparency, tissue paper…
Jean-Babtiste Labrune pointed out this planar coil calculator >> http://www.circuits.dk/calculator_flat_spiral_coil_inductor.htm
Ingredients: copper tape, conductive fabric, stainless steel thread, gold leaf, paper, wood, fabric, double-sided sticky (studio tack),
Equipment: Lasercutter, vinylcutter (Craft Robo), scissors, paint brushes, tool
Downloads:Illustrator file of speaker coils, some of which were hand drawn
Create a coil shape
Draw and scan or create in software.
Cut the coil
Depending on what material you are using (copper tape, conductive fabric, thread, paint…) you’ll have different ways of creating your coil.
Copper tape on Craft Robo, double-sided sticky on lasercutter
Conductive fabric tape on lasercutter
Conductive fabric with
Adhere coil to membrane
Steel thread on masking tape
Sound amplification circuit
Using a TIP 120to control a 5V or a 9V power supply from a microcontroller, in this case a sound circuit taken from a toy that plays the same song every time the button is pressed.
Tom Igoe’s schematic >> http://itp.nyu.edu/physcomp/Tutorials/HighCurrentLoads