The CU also accounts for the efficiency
of the room in redirecting and inter-
reflecting the incident light that strikes its
surfaces. This is affected by the room’s
proportions as well as its reflectances. A
large, low room is more efficient than a
tall, narrow one. In the large, low room,
little incident light is interrupted by the
walls; almost all of the light is received
directly by the workplane. In a high,
narrow room, much of the incident light
strikes the walls at least once before
reaching the workplane, sometimes
being reflected between several sur-
faces before reaching the task.These variables produce an infinite
number of CUs for each luminaire. For prac-
tical purposes, they are reduced to a group
of figures for typical room proportions and
reflectances.
Room Cavity Ratio.The CU is found by
checking the manufacturer’s coefficient-of-
utilization table, which is usually published
on the back of product data sheets. In order
to use the CU table, it is first necessary to
calculate the room cavity ratio.
The room cavity ratio provides an
expression of the efficiency of room propor-
tions. To determine this ratio:RCR=
+
×
5( ) (hl w)
lwwherehis theheight of the ceiling above the
task surface,lis thelength of the room, and
wis thewidth of the room. The task surface
is usually considered to be 2 ft 6 in AFF
(abovefinishedfloor) (figure 10.9).
A sample coefficient of utilization table
for a compact fluorescent, open-reflector
downlight is shown in table 14 in the Appen-
dix.Example
Calculate the average maintained illumi-
nance on the workplane in a 15 ft × 30 ftPHOTOMETRICSFigure 10.9The room cavity used in the abbreviated lumen or zonal-cavity method.