Handbook for Sound Engineers

(Wang) #1
Acoustics for Auditoriums and Concert Halls 185


  • The clear spacing of the coffering should be, in
    general, smaller in every direction than 0.5 times the
    wavelength in case of resonance, but not fall short of
    0.5 m (1.7 ft).

  • The minimum size of the vibrating panel must not
    fall short of 0.4 m^2 (4.3 ft^2 ).

  • The air-space damping material should be attached to
    the solid wall so that the panel vibration is not
    impaired in any way.

  • The sound absorption coefficient depends on the Q
    factor of the resonance circuit and amounts at the res-
    onance frequency to between 0.4 and 0.7 with
    air-cushion damping and to between 0.3 and 0.4
    without air-cushion damping. At an interval of one
    octave from the resonance frequency one must
    reckon that the sound absorption coefficient is
    halved.


An effective method for increasing the acoustically
effective resonance frequencies of panel resonators
consists of reducing the vibrating mass of heavy panels
by means of holes arranged in defined patterns. In this
case the correlations are governed by analogous regular-
ities, if the area-related mass mc of the panels is replaced
by the effective hole mass mcL. For circular holes of
radius R and a hole-surface ratio H Fig. 7-48, the hole
mass is calculated as


(7-67)

where,
mcL is the area-related air mass of circular openings in
kg/m^2 (lb/ft^2 ),
l* is the effective panel thickness with due consider-
ation of the mouth correction of circular openings of
radius R in meters (ft)


, (7-68)

is the hole-area ratio according to Fig. 7-47 for
circular openings

. (7-69)


Provided the hole diameters are sufficiently narrow,
the damping material layer arranged between the perfo-
rated panel and solid wall can be replaced by the friction
losses produced in the openings. By using transparent
materials—e.g., glass—it is possible to fabricate opti-
cally transparent, so-called micro-perforated absorbers.
The diameters of the holes are in the region of 0.5 mm

(0.02 in) with a panel thickness of 4 to 6 mm (0.16 to
0.24 in) and a hole-area ratio of 6%. For obtaining
broadband sound absorbers, it is possible to resort to
variable perforation parameters (e.g., scattered perfora-
tion) varying thickness of the air cushion and composite
absorbers combined of various perforated panels.

A very recent development are microperforated foils
of less than 1 mm (0.04 in) thickness which also produce
remarkable absorption when placed in front of solid
surfaces. The transparent absorber foil can be advanta-
geously arranged in front of windows either fixed or also
as roll-type blinds in single or double layer.^44

7.3.4.4.3 Helmholtz Resonators

Helmholtz resonators are mainly used for sound absorp-
tion in the low-frequency range. Their advantage, as
compared with panel absorbers (see Section 7.3.4.4.2),
lies in their posterior variability regarding resonance
frequency and sound absorption coefficient as well as in
the utilization of existing structural cavities which must
not necessarily be clearly visible. According to Fig.
7-49, a Helmholtz resonator is a resonance-capable
spring-mass system which consists of a resonator
volume V acting as an acoustical spring and of the mass
of the resonator throat characterized by the opening
cross section S and the throat depth I. In resonance
condition and if the characteristic impedance of the
resonator matches that of the air, the ambient sound
field is deprived of a large amount of energy. To this
effect a damping material of a defined specific sound
impedance is placed in the resonator throat or in the
cavity volume.

mcL 1.2**l*
H

= ---- -

** 0.37 for U.S. system

l*1S
2

| +---R

H

H SR

2

ab

= ---------

Figure 7-48. Hole-area ratio of perforated panels with
round holes.

a

R

b
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