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#Speaker enclosure design theory driver
This can be calculated using the TSP of the driver (Thiele-Small-Parameters). The theory of a loudspeaker enclosure is to present a well-defined air volume to the driver to achieve a useful frequency response. “The theory of a loudspeaker enclosure is that it should simulate an infinite space behind an infinite plane in which the speaker driver is mounted, and the reasoning behind spherical or egg-shaped enclosures goes that they better achieve that aim through presenting a uniform inner surface without the corners of a more conventional rectangular enclosure.” Posted in 3d Printer hacks Tagged 3d printed speaker, audio, hi-fi, loudspeaker, speaker Post navigation
These aren’t the first 3D-printed enclosures we’ve seen, but if you’re after something truly unusual how about an electrostatic? What would be the effect of filling that air gap with something of higher mass, for example, and should the parameters of the egg shape and the port be derived for a particular driver by calculation from its Thiele-Small parameters. This is an interesting design and approach to speaker cabinet construction, but we think from an audio perspective its one that will be well served by more development. Instead, he created a significant air gap between two layers which he hopes will create the same effect. Conventional speakers try to achieve this by using high-mass and particulate materials, but 3D-printing does not lend itself to this. ’s enclosures 3D-printed ported enclosures achieve this more easily than traditional methods of building this shape.Ī loudspeaker enclosure is more than just a box though, whatever material it is made from must adequately dampen any resonances and absorb as much energy as possible. The theory of a loudspeaker enclosure is that it should simulate an infinite space behind an infinite plane in which the speaker driver is mounted, and the reasoning behind spherical or egg-shaped enclosures goes that they better achieve that aim through presenting a uniform inner surface without the corners of a more conventional rectangular enclosure. This applies in particular to the loudspeaker, and with that aim has created an eye-catching set of 3D-printed egg-shaped enclosures. There are few limits to the extent audiophiles will go in their quest for the perfect sound.