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Bright
Prospects
for Lighting
Retrofits
Great potential
for electricity savings lurks in the alleys, hallways, and stairwells,
and even behind the exit signs of multifamily buildings. But to realize
that potential is not always as easy as screwing in a light bulb. Welcome to multifamily
lighting. Simple in concept--but in practice, its seemingly "minor"
technicalities tend to trip up the unwary.
Common Problems
Are Fading Fast
The replacement of incandescent lighting--particularly
hallway fixtures and exit signs that consume electricity 8,760 hours a
year in many multifamily buildings--with compact fluorescent lamps (CFLs)
yields substantial energy savings and should be easy to promote. It is
not uncommon to find 60W bulbs in the hallways and 20W incandescent bulbs
(sometimes two) in the exit signs. In Wisconsin, the average price of electricity
is 7¢ per kWh. I like to position the owner of the building under
one of these existing fixtures and start punching keys on my calculator.
"Your existing energy charge for this light
alone is $37 annually," I say. "By converting to a compact fluorescent
lamp, your new energy bill will be $9. Although the new lamp and fixture
will cost about $30, the cost for the fixture is about the same as the
savings you will enjoy in just one year."
With savings potential like this, it is puzzling
that owners and managers would ever forgo a lighting retrofit. One reason
may be that the technology is new and the products unfamiliar. Is a tapered
globe more aesthetically pleasing than a U-shaped biaxial tube, or is it
just more familiar? Also, for many people fluorescent lighting means a
cold light that casts a greenish hue. Often these building owners must
see the better color temperature and rendition of newer fluorescent lamps
to believe the difference. In common areas, we usually use CFLs with color
temperatures of about 2,700K, and full-sized fluorescents in the 3,500K
range, both with good color rendition.
Another consideration is length. Standard CFLs
will not fit into some existing residential fixtures. A common mistake
is to install shorter, lower-wattage lamps that do not produce enough light
for the task. A better solution is either to replace the fixture or to
leave it as is and focus on another area for the retrofit.
In the past, it was difficult to find an appropriate
replacement for high-wattage incandescents in areas that need the higher
illumination. Retrofitters often addressed this problem by installing multiple
CFLs (for example, three 13W CFLs to replace one 150W incandescent). There
is a new 38W CFL that is rated at 2,850 lumens (Lm)--about the equivalent
of a 150W incandescent. The lamp carries a higher price tag than most CFL
retrofits, but it is usually quite cost-effective, and the electronic ballast
provides instant-on, the ability to start at 0deg.F, and good power quality.
Some compact fluorescent lamps will have trouble
starting in cold weather, especially when the temperature drops below 0deg.F.
When installing fluorescent fixtures outside, use enclosed fixtures, which
keep the bulbs warmer by retaining more of the heat they generate. For
extremely cold weather applications, lamp ballasts and fixtures are available
that start reliably down to -20deg.F. In fact, we recently installed compact
fluorescents in New London, Wisconsin, that had no problem starting at
-24deg.F.
An additional problem in multifamily installations
can be theft and vandalism. Although it is tempting to use the convenient
screw-in replacements for incandescents, a $15 screw-in conversion can
become a screw-out conversion when nobody is looking, turning your energy-saving
project into a screw-up conversion!
Doing it right the first time can be a challenge,
but it is a goal worth pursuing. It's worth it to pay a little extra up
front for quality, because the savings are still so attractive. This means
converting the fixture, not just the lamp--that is, doing hard-wired installations
rather than screw-in conversions (with the exception of exit-light kits).
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Helpful Terms
Lumen (Lm) is the quantitative measure
of a lamp's brightness. A 75W incandescent bulb has 1,200 initial Lm. An
18W CFL has 1,100 Lm.
PL lamp stands for Phillips Lighting's
twin-tube CFL, the first bulb of its kind to be made available in this
country. Other manufacturers, of course, balk at the use of this brand-specific
terminology and call compact fluorescents biaxials, twin tubes, or
by their own brand name shorthand, such as Osram's EL.
Lamps with four lengths of tubing are called
quad lamps, Q lamps, or double-twin tubes.
U tube, a term that describes the general
shape of the bulbs, can refer to a U-shaped standard fluorescent tube 2
ft long and 11/2 inches in diameter, or to a type
of compact fluorescent.
Cap light refers to encapsulated tungsten
halogen lamps. The halogen capsule is encased in a heavy glass shell that
looks similar to a standard light bulb.
Color rendering index (CRI) is a scale
for rating the way objects look under a particular light. The color rendering
index associated with incandescent light is 100. Compact fluorescent bulbs
have CRIs in the low 80s, while older long-tube fluorescents usually have
CRIs in the 60s.
Color temperature measures the color of
the tube itself. Color temperatures are 2,700K for "warm," redder
applications; 3,500K for balanced color applications; and 4,100K for "cool,"
bluer applications.
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Retrofit in Haste--Repent at Leisure
Don't take the easy way out. Consider a common
energy savings opportunity--basement lighting in large residential buildings.
It is easy to specify a circular fluorescent for installation in a porcelain
socket holding a 60W bulb. (The higher-wattage circular screw-in fixture
was once popular because it does not hang down as a CFL screw-in would.)
Sure, the circular fluorescent's 32 W represents a 47% reduction in electrical
usage; but it also represents a lost opportunity to install a 15W compact
fluorescent fixture that could save 75%. So auditors should have fixtures
in their inventory.
The retrofit involves removing the porcelain
fixture to reveal the junction box and wire terminals and connecting the
two wires to the ballast on the new fixture. The hard-wired retrofit's
advantages are its low cost, theft-resistance, and the horizontal orientation
of the CFL U tube (which provides maximum light output and fits the lower
ceilings found in basements).
I often recommend fixture replacement in multifamily
hallways. The likelihood of unauthorized removal of the bulb is reduced
and can be virtually eliminated with vandal-resistant fixtures. These "tough
guys of the lighting inventory" are equipped with polycarbonate lenses
and can be installed with tamper-resistant or set screws, such as TORX,
Allen, or Roberts, all of which can be turned only with special tools.
The lens can take a beating without breaking. No fixture will stand up
to a determined effort by a tool- or weapon-wielding villain, but fixtures
designed for high-security institutions come close, and may be appropriate
in some buildings.
| Replacements for Incandescent Bulbs
It is difficult to make any generalization about the light output of
a given wattage of lamp because it differs among manufacturers. However,
this table suggests a range of replacement wattages that reflects what
we have found to be reasonable in local multifamily housing. Wall color,
daylighting, lamp spacing, and orientation will also affect lamp selection.
Note that the actual wattage saved by CFLs takes into account the extra
few watts used by the ballast, which is not always included in the lamp's
"name."
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Compact
Fluorescent |
Equivalent
Incandescent
Bulb |
Total
Watts
Saved |
| 5W twin tube |
25W |
18 |
| 7W twin tube |
34W |
25 |
| 9W twin tube |
40W |
29 |
| 13W twin tube |
60W |
42 |
| 15W globe or cylinder |
60W |
45 |
| 18W double twin tube |
75W |
51 |
| 22W circle |
60W |
35 |
| 23W triple tube |
90W |
67 |
| 27W triple tube |
100W |
73 |
| 28W quad |
100W |
70 |
| 30W circle |
135W |
105 |
| 38W double-D tube |
150W |
112 |
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Exit Lights: Better
Mousetraps
Exit light fixtures and conversion
kits now come in a variety of technologies, ranging from an exotic tube
of glowing tritium gas, for those who like their signs "nuclear powered,"
to low-voltage light-emitting diodes. The radioactive tritium exit signs
are high on first costs, are not connected to the power grid, and have
no yearly energy charge associated with them, but they gradually dim and
must be replaced--presenting a hazardous-waste disposal problem. However,
they require no wiring or power supply, so they are considered suitable
for adding signs where no electric circuit exists.
Light-emitting diode (LED) sign
fixtures and screw-in retrofit kits are extremely low wattage--1.8 W and
1.1 W respectively. They are available with 25-year warranties, and manufacturers
claim 30 to 100 years of expected life. If you do life cycle costing and
calculate the savings from never buying a replacement bulb on top of the
typical energy savings of 38 W (about $25 annually) the initial cost of
this technology is insignificant. Remember, exit lights are on 8,760 hours
per year. Costs are becoming more competitive also. We purchased fixtures
for about $65, and the retrofit kits are in the $25-$30 range. Like other
conversion kits, the LED socket adapters fit medium, intermediate, candelabra,
and bayonet bases.
Electroluminescent lighting (EL)
is a relatively new technology that consists of a phosphor-coated dielectric
panel sandwiched between two layers of an aklar material. When the phosphors
are excited, the whole panel glows evenly, and a stencil placed in front
of the panel spells EXIT. These signs can run off AC power or batteries
and draw only 1 W.
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Table 1.Comparison of incandescent
to
CFL and LED exit light conversions
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Incandescent
40W total |
PL-7 and
ballast
conversion
kit
9W total |
LED
conversion
kit
1.1W total |
| First cost |
$2 |
$17 |
$30 |
| Bulb replacement |
$14 |
$19 |
N/A |
Energy cost
for 50,000 hours
(life of PL-7 ballast) |
$140 |
$32 |
$4 |
| Life cost over 5 yrs |
$156 |
$68 |
$34 |
| Cost per year |
$31 |
$14 |
$7 |
A Long Life of Savings
Some contractors' estimates include savings from
labor avoided by not changing bulbs so often. I have never included this
elusive value in my payback calculations. But I do inform the maintenance
staff that the average life expectancy of the new bulbs is 10,000 hours
and that they will be replacing bulbs less frequently. I like to get the
staff who are directly involved to help me convince the owner to invest
in lighting improvements. The prevalence of long-life incandescents in
multifamily buildings indicates that labor is a consideration of apartment
owners and managers.
One building we retrofitted had 40W long-life
incandescent bulbs in hallway fixtures with white globes. They delivered
only 270 lumens--less than a 34W standard incandescent. Long-life light
bulbs get some of their longevity by trading off some luminous efficiency.
In fact, the lumen output from a long-life bulb is about 20% less than
that of a standard incandescent of the same wattage.
We retrofitted the fixtures with larger globes
to accept the longer compact fluorescent lamps, and reduced wattage from
the nominal 40 W to 9 W, while increasing lumens to 575 per lamp. The hallways
have more light than before, and the lamps are expected to last about four
times as long as the old "long-life" bulbs. If we had wanted
even more light in the halls of these buildings, a transparent or clear
prismatic globe could have been used.
Whether labor savings are considered or not, the
cost of bulb replacement should be evaluated along with energy costs for
a life cycle cost analysis of each retrofit measure. Life cycle costing
can show that a $15 compact PL-13 costs less than a 75¢ incandescent
bulb, with reduced energy costs and less frequent bulb replacement. Remember
to include the energy consumption attributed to the ballast when calculating
savings for new CFL installations (see "Replacements
for Incandescent Bulbs," p. 42).
When replacing existing incandescents with CFLs,
retrofitters must choose between separate tube and ballast combinations
or self-contained units that have both components. Since the ballasts last
much longer than the tubes, replacement costs will be less for separate
(modular) tubes and ballasts. Some one-piece units have casings that make
them look more like traditional light bulbs, but their lenses reduce the
light transmitted. Such loss of light output may result in specification
of a higher wattage than would be appropriate if the compact tube were
"naked."
Reflectors can rescue some of the light lost
in fixtures. CFLs used to replace incandescents in recessed-can fixtures
do not direct the light output optimally. If a CFL is held end-on close
to a wall, the end of the tube will cast a shadow. A reflective collar
can direct some of the light downward to more closely mimic the old illumination
pattern. Prepackaged compact fluorescent floods and spots are also available
with built-in reflectors. The three-piece versions (separate lamp, ballast,
and reflector) cost little at replacement time, because only the lamp needs
to be changed. Ballasts typically last for 50,000 to 65,000 hours, while
lamps need replacement at 10,000 hours.
Retrofitters can choose new fixtures that increase
light quality, and can also control the direction of light output. What
area needs to be illuminated: ceiling, floor, or walls? One Milwaukee building
needed security lighting in a back alley at night, but apartment windows
faced the fixtures. We used a fixture that illuminated the alley but was
covered on top, so light did not spill into the rear-facing bedroom windows.
Selection of a fixture to meet the retrofit situation
exactly can prevent problems that may occur when old fixtures meet new
lamps. Fixtures light the way to lower operations and maintenance costs,
better lighting quality, and persistence, as well as energy savings.
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Sample Lighting Audit
Form
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| Location |
Old Fixture Type |
Suggested Retrofit |
Watts per Fixture (old) |
Watts per Fixture (new) |
Number of Fixtures |
Total Watts Saved |
Daily Burn Hours |
Total
Annual kWh Saved |
$ Saved
per Year (at 6.5 ¢/kWh) |
Cost
per Fixture |
Total
Cost |
| Basement ceiling |
Porcelan socket |
Flour. drum |
40 |
13 |
19 |
513 |
24 |
4,494 |
$292 |
$22 |
$419 |
| 1st floor hallway |
Incand. drum |
Ovel flour. fixture |
40 |
13 |
14 |
378 |
24 |
3,311 |
$215 |
$30 |
$420 |
| 2nd floor hallway |
Incand wall sconse |
CFL wall sconse |
40 |
13 |
5 |
135 |
24 |
1,183 |
$77 |
$43 |
$215 |
| Exterior |
Incand. coachlight |
Brass CFL
coachlight |
40 |
20 |
10 |
200 |
12 |
876 |
$57 |
$55 |
$550 |
| Exit |
Incand. |
LED
fixture |
40 |
4 |
18 |
648 |
24 |
5,676 |
$369 |
$64 |
$1,152 |
| Total |
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1874 |
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15,540 |
$1,010 |
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$2,756 |
| The audit form above was completed
for three buildings we retrofitted in New London, Wisconsin, at the end
of 1994. This represents the common areas only and, although the owner
was using only 40-watt incandescents for everything, the retrofit was still
very cost-effective. |
Figure 1.Comparison of utility bills before and after
retrofit. |
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| The actual savings from five months
of billing data (January through May 1994 compared to the same months in
1995) for the three buildings are shown in the figure to the right. The
bills went down by $373 total for those five months. |
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Larry Hasterok is an energy analyst with the
Wisconsin Energy Conservation Corporation, a nonprofit energy consultant
in Madison, Wisconsin.
Note: The original version of this article
was printed in the Nov/Dec 1990 issue of Home Energy.
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