Well, that's only partly true, and only for "normally incident" sound, which means sound waves that strike the front surface of the absorber head-on, at an angle of 90°. For waves that hit it at any other angle, then the wave will travel through a lot more insulation, and a lot more air, before it reaches the wall behind. So in effect, it "sees" the distance as being much greater, and therefore the absorber works down to much lower frequencies than you'd expect for waves that are not "normally incident". A wave hitting at an angle of 30°, for example, "sees" a path that is twice as long, so it would get the same effect as a wave hitting head on, but down to half the frequency. When you consider that most waves in a room are not arriving "normal" to the surface, you can understand that the effective frequency is a lot lower than you'd think.to be effective for a specific fq a porous absorber has to have a quarter of its wavelength distance to the hard surface behind it. If I would want to decrease the most problematic area of modal resonance of about 50Hz, the distance to the wall would therefore have to be around 170cm!!!
Also, the effect doesn't suddenly drop to zero for frequencies lower than 1/4 wave length: Even for normally incident sound it's a gradual roll-off, and absorption is still very effective down to much lower frequencies. Yes, it is optimal for frequencies at the 1/4 wave distance, but for frequencies lower than that (longer wavelengths) you are still getting very useful absorption. Check the absorption coefficients for 4" OC-703 mounted flat on the wall, for example, and you might be surprised....
There's also the additional point that you don't have to have extremely thick insulation to get useful absorption: In fact, even at 7% of the wavelength you are still getting decent absorption.
That's why porous absorbers in general are recommended for bass trapping: They can be effective down to very low frequencies. And that's also why superchunks are an excellent choice: the front face is angled, so the apparent depth is greater due to most sound arriving at non-normal incidence; there's a lot of depth (a wave arriving at a glancing angle sees upwards of 60cm of absorption), and the corner location makes them between two and four times more effective than just plain absorption over a flat wall.
The superchunks in the corners will take care of most of that, and the absorption on the back wall will do the rest.I guess you imply that the low frequencies around 50Hz will not be affected by that and that I will probably never loose any of these? What would be the way to get rid of them?
Here's a couple of graphs from a room I treated last year, showing the difference in response before and after adding a 4" panel of 703 to the rear wall, over a 30 cm gap. This room already had superchunks in the rear corners, but still had some issues with the length mode.
Before 703: And after installing the 703: That's just how the frequency response changed. The time-domain response tells you a lot more about how effective this is.
Water fall plot, before 703: And afterwards: Note particularly what happened to the modes at just under 80 Hz, and just under 40 Hz. They smoothed out quite neatly. And that was just from a single panel of 4" 703 a few inches in front of the rear wall. (Later treatment hit some of the other issues you can see in the graphs, but that was a very clear example of how effective absorption can be at very low frequencies.)
Yup. Very true. Don't go there.... Modes are very tight, very narrow band resonance. Hard to hit with a fixed tuning device. If the tuning can be varied easily, then you stand a better chance, but you still need a huge air volume inside in order for the resonator to be effective. Absorption is much easier.Helmholtz resonator? I got quite a lot of people telling me not to go into building these, as they are very difficult to tune ...
VPR devices do work well, but they are fairly new and the math isn't well understood yet. Or at least, there isn't a lot of verifiable independent research out there about how they work, except for some done in Germany, I think. Unfortunately, as you mentioned, the research institute patented the device and clammed up on their research, releasing only bits here and there, and since it is patented, nobody else is bothering to build them and test them in different configurations, and in independent acoustic labs. Until that happens, I think I won't be buying any. Or building them for my clients either!
Porous absorbers, on the other hand, are a well-known, well-understood device, tested endlessly all over the world, with widely available results. There's no secrets as to how they work....
- Stuart -