108 Chapter 5
Draperies are also porous absorbers of sound.
Included in the drapery category are drapes, curtains,
tapestries, and other fabric wall-hangings, decorative or
otherwise. Besides the type and thickness of material,
the percent fullness has an effect on how well draperies
absorb sound. (The percent fullness is a representation
of the amount of extra material in the drapery. For
example, 100% fullness would mean that a 3.0 m wide
curtain actually consists of a 6.0 m wide piece of mate-
rial. Similarly, 150% fullness would indicate that a 3.0 m
wide drape consists of a 7.5 m wide piece of material; a
6.0 m wide piece of material being used for an 2.4 m
wide drape, etc.) Fig. 5-18 shows the absorption coeffi-
cients for draperies with different percent fullness.^22
While spacing draperies from the wall does increase
absorption slightly, it would not appear to be as signifi-
cant as percent fullness, as indicated by Fig. 5-19.^22
5.2.3 Discrete Absorbers
Discrete absorbers can literally be anything. Even an
acoustical tile or foam panel is a discrete absorber. The
absorption per unit of a tile, panel, board, person, book-
shelf, equipment rack, etc., can always be determined. In
the context of acoustical treatments, there are two main
classes of discrete absorber that should never be ignored:
people and furnishings.
5.2.3.1 People and Seats
In many large spaces, people and the seats they sit in will
be the single largest acoustical treatment in the room.
Any acoustical analyses of sufficiently large spaces
should include people in the calculations. How the seats
behave acoustically when they are empty is another
important consideration. Empty wood chairs will not
absorb as much as the people sitting in them. A heavily
padded seat may absorb just as much sound as a seated
individual. A chair that folds up when not in use may
have a hard, plastic cover on the underside of the seat
that will reflect sound. Perforating the cover to allow
sound to pass in through the bottom of the chair when it
is folded up may be a worthwhile consideration for some
applications. For more information on the absorption of
people, seats, and audience areas in general, refer to
Section 7.3.4.4.4.
5.2.3.2 Acoustical Baffles and Banners
In very large rooms, such as domed stadiums, arenas,
gymnasiums, factories, and even some houses of
worship, absorbers need to be placed high on the ceiling
to reduce reverberant sound. Installing spray applied
acoustical treatments in such spaces is often uneconom-
ical because it would be too labor-intensive. To solve
this problem, prefabricated acoustical treatments that
hang from the ceiling are often used. Acoustical baffles
are typically 61 cm × 122 cm (24 in × 48 in)—or some
other relatively manageable size—and are often approx-
imately 3.8 cm (1.5 in) thick. The core material is often
a rigid or semi-rigid mineral fiber, such as glass fiber,
with a protective covering of polyester fabric, rip-stop
nylon, or PVC. Acoustical foam panels and other porous
Figure 5-18. The effect of fullness on the absorption of cot-
ton cloth curtain material, 500 g/m^2 (14.5 oz/yd^2 ).^22
Figure 5-19. The effect of mounting over an air space on
the absorption of velvet cloth curtain material, 650 g/m^2
(19 oz/yd^2 ).^22
125 250 500 1k 2k 4k
1.40
1.20
1.00
0.80
0.60
0.40
0.20
0.00
Octave band center frequency—Hz
ASAB
14% fullness
33% fullness
100% fullness
125 250 500 1k 2k 4k
1.40
1.20
1.00
0.80
0.60
0.40
0.20
0.00
Octave band center frequency—Hz
ASAB
Air space = 10 cm (3.9 in)
Air space = 0 cm (0 in)
Air space = 20 cm (7.9 in)