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Home Energy Magazine Online January/February 1997
Florida House Aglow with Lighting Retrofit
by Danny Parker and Lynn Schrum
Danny Parker is a principal research scientist
and Lynn Schrum is a research assistant at FSEC.
In a residential lighting retrofit, how
much energy can be saved with current technology? The Florida Solar Energy
Center decided to find out by retrofitting every lamp in a Miami home.
 Most
lighting studies focus on average lighting energy use or on how much energy
can be saved by retrofitting large numbers of homes. However, at the Florida
Solar Energy Center (FSEC), we were interested in finding out how much
lighting energy we could save in a single house. We picked one house with
high utility bills and extensive interior lighting, thoroughly monitored
it, and retrofitted every light we could. The study also helped us learn
what sort of monitoring is most useful, and how residents respond to efficient
lighting.
What We Did and How We Did It
First, we instrumented the house, a 1,341 ft2
single family South Miami home. We began monitoring it in baseline condition
on April 27, 1995. Our initial method of monitoring was to isolate the
lighting and plug loads from other major loads. We metered the electrical
use of the refrigerator, the clothes dryer, and the heating and cooling
systems in addition to total household usage. We subtracted the major loads
from the total to isolate miscellaneous plug loads and lighting. If only
lighting was altered, we could use the differences in the miscellaneous
loads before and after the retrofit to estimate lighting energy savings.
However, the household had a lot of miscellaneous
plug loads, including three TVs, two VCRs, six ceiling fans, a home computer
system, electric clocks, a dishwasher, and a vacuum cleaner (see "Phantoms
Strike Miami"). In order to keep these miscellaneous loads from distorting
the data, we installed individual time-of-use light loggers or plug loggers
on each of the lighting fixtures in the home to establish the actual on-time
of each. This let us assess how monitoring pure lighting loads compared
with calculating energy savings by subtraction.
We began light logger monitoring on August 8,
1995. We didn't have enough lighting loggers for all the lamps in the house,
so we had to capture the pure lighting loads by metering two groups of
fixtures at different times.
We inventoried the home's lighting, and found
40 lamps on 26 switches with a total connected load of 2.5 kW (see Table
1). In general, the lighting consisted of incandescent A-lamps of various
wattages.
 |
| Researchers learned some lessons about placing loggers
in enclosed fixtures. This logger continued to function, even after melting
in an incandescent fixture. |
| Table 1. Lighting Inventory Before and After Retrofit. |
| Lamps Before Retrofit;Replacement Lamps |
| Kitchen |
| Counter |
60W incand. globes (2) |
15W CFL (3) |
| Overhead |
100W, 60W, 25W incand. |
30W circline (1) |
| Under counter |
20W FL tube |
-- |
| Dining room |
| Over table |
50W halogen |
-- |
| Aquarium |
25W incand. |
11W tube fluorescent |
| Living room |
| Floor lamp |
75W incand. |
15W CFL |
| Overhead anteroom |
60W incand. globe |
18W CFL |
| Table lamp |
75W incand. |
22W circline |
| Table lamp |
100W incand. |
22W circline |
| Florida room |
| Overhead |
60W incand. globe |
15W CFL |
| Table lamp |
100W incand. (2) |
22W circline |
| Study |
| Desktop lamp |
100W incand. |
15W CFL |
| Portable swing lamp |
13W CFL |
-- |
| Table lamp |
75W incand. |
22W circline |
| Hallway |
| Overhead lamp |
60W incand. |
-- |
| Bedroom |
| 2 table lamps |
60W incand. (2) |
22W circline (2) |
| Master bedroom |
| 2 table lamps |
60W incand. (2) |
42W halogen |
| Bathroom |
| Vanity |
55W incand. (4) |
15W CFL (3) |
| Master bathroom |
| Vanity |
60W incand. (3) |
40W incand. globes (3) |
| Garage |
| General overhead |
100W incand. globe |
15W CFL |
| Desk lamp |
100W incand. |
22W circline |
| Garage door |
55W incand. |
42W halogen |
| Outdoors |
| Front porch |
60W incand. globe |
60W incand. globes (2)¥ |
| Back porch |
65W PAR (4)
75W PAR
75W PAR |
¥
45W PAR
¥ |
| --: |
No change |
| PAR: |
Parabolic aluminized reflector, commonly known as floodlights |
| ¥: |
Motion sensor installed |
Energy Use Before the Retrofit
Both the subtractive method and the logging method
showed a lot of lighting energy use. From five months of baseline monitoring,
we estimated annual use at over 4,050 kWh! This is high, although a recent
widescale monitoring project by Tacoma Public Utilities (see "Shedding
Light on Home Lighting Use," p. 15) found one home using 7,400 kWh per
year for lighting. More enlightening than total energy use was what we
learned about where in the house lighting electricity was consumed most
(see Table 2). We looked at both the average number
of hours fixtures were used within each room and the fraction of the measured
daily lighting energy that was used in each space. Like the Tacoma study
and a 1993 phone survey by the Lighting Research Center, we found that
outdoor and kitchen lighting comprised the largest fraction of total lighting
consumption.
 |
| Outdoor lights offer big potential savings, but pose
problems for retrofitting and monitoring. These lamps were retrofitted
using a motion sensor which provided some savings in the early evening.
However, the residents usually overrode the control, and left the light
on all night. To add to the problems, a dead moth on the photosensor disrupted
the logging. |
We expected the electric lighting loads to vary
seasonally with day length. An early study by Pacific Northwest Laboratories
(PNL) found a 40% variation from a high in December to a low in June. The
recent Tacoma study showed 30% less lighting energy use in the lighter
versus the darker months.
| Table 2. Daily Electric Lighting Energy by Use |
| Location |
Daily kWh |
% of Total |
Average On
Hours/Day |
| Outdoors |
3.7 |
33.6 |
10.1 |
| Kitchen |
2.6 |
23.1 |
8.0 |
| Garage |
1.3 |
12.1 |
13.4 |
| Study |
1.1 |
9.8 |
6.8 |
| Dining table |
| fixtures |
0.6 |
5.3 |
5.3 |
| Master |
| bedroom |
0.5 |
4.6 |
4.3 |
| Bathroom |
0.3 |
2.5 |
1.3 |
| Aquarium |
0.2 |
2.0 |
14.7 |
| Bedroom |
0.2 |
2.0 |
1.8 |
| Florida room |
0.2 |
1.9 |
1.1 |
| Living room |
0.2 |
1.7 |
0.9 |
| Master |
| bathroom |
0.1 |
0.8 |
0.5 |
| Hallway |
0.1 |
0.1 |
1.0 |
In Miami, the shortest day is 10.6 hours and
the longest is 13.7 hours, a 23% difference in available daylight hours.
We found greater loads during the month of December due to holiday lighting
(see "The Electric Bill That Stole Christmas"). The
residents took a ten day vacation in July, which combined with longer days
to reduce lighting use in that month. Eliminating these exceptional months,
the variation in use between June and November was 24%.
Making the Switch
Over a couple of days in early December 1995, we
changed the lighting system in the home to efficient lamps and fixtures.
We installed 27 new lamps or controls. We timed the installation to coincide
with the winter solstice, so we could obtain similar seasonal data before
and after the change. In most cases, we installed CFLs in frequently used
interior fixtures, and motion sensor controls with PAR halogen lamps in
exterior lights. We used incandescent halogen bulbs for infrequently used
and hard-to-fit fixtures.
The connected household lighting load dropped
from 2.5 to 1.1 kW--a reduction of 56%. In order to examine savings, we
continued to log energy use for another six months.
 |
| Project installers were aided by the wide array of
bulbs now available for retrofit purposes. This 5-inch triple tube 15W
CFL worked well for several tight corners. |
Not Perfectly Smooth Sailing
Before ordering equipment, we examined and measured
each of the fixtures and lamps that we wanted to alter. This made for a
relatively trouble-free installation. As usual, the need for very short
CFLs was apparent during the retrofit. Fortunately, the new triple-tube
15W CFLs were small enough to fit in many of the tight fixtures. The exterior-lighting
motion sensors proved to be more difficult to install than we had anticipated
because we needed to cut holes in the porch eaves for the control boxes.
Still, it only took us a day to retrofit the whole home.
Phantoms Strike Miami
Monitoring whole-house demand and subtracting the
major loads is a good way to calculate changes in lighting use. However,
miscellaneous loads affect the result. Since the first retrofit home was
completed, we have started monitoring and retrofitting two more homes.
In a field evaluation of one of them, we metered miscellaneous appliances
with a sensitive digital power analyzer. These "other" loads, particularly
the ones that were on all the time, were surprisingly large. While other
homes probably don't have the same constant load as this one, it shows
how "other" can account for a big part of the bill. Auditors attempting
to monitor lighting loads need to be careful not to count these loads as
lights.
Equipment left on included the aquarium pump,
a couple of portable phones, and a security system. Items that had notable
"phantom" loads--power use that takes place when the equipment is off--were
the two TVs, a VCR, a portable stereo, and a laser printer (see HE
July/Aug '96, p. 42, "Off is a Three-Letter
Word").
We didn't meter the clocks or the flashlight
charger, but they may have added a bit more. The total constant load was
88 W, which works out to 771 kWh per year. This equals about 4% of the
house's total annual electricity consumption.
| Miscellaneous Loads |
| 100-gal salt water aquarium pump |
41 W |
| Entertainment center: 36-in TV, VCR, decoder |
160 W-205 W, depending on screen; 18 W quiescent |
| Portable phone #1 |
2.1 W in use, 1.6 W standby |
| Portable phone #2 |
2.0 W in use, 1.2 W standby |
| Security system |
15 W |
| Monitor & computer |
115 W |
| Laser printer |
250 W active, 6 W quiescent |
| TV |
115 W on, 5 W off |
| Portable stereo |
7 W on, 2 W off |
| Toaster oven |
460 W toasting |
| Espresso maker |
360 W on |
|
Converting the lighting fixture over the dining
room table proved an insurmountable challenge. This is an attractive fixture
that is used to illuminate the table's centerpiece. Its dimmer controls
a low-voltage miniature 50W halogen PAR. This fixture is frequently left
on for long periods of time--an average of 9.4 hours per day--and is seldom
dimmed.
At first, we planned to provide a motion sensor
control to turn off the fixture when no one was present. However, the switch
wiring was in a solid concrete wall, making installation difficult, to
say the least. We couldn't install a CFL in the fixture because the residents
desired continuous dimming. CFL dimming ballasts that use conventional
dimmers have since become available.
There was a second dining table in the "Florida
room," a glassed-in porch common in our state. The lamp over this table
was less frequently used and proved easy to retrofit. We replaced its 60W
incandescent globe with a 15W CFL globe.
In the monitoring, we encountered difficulties
using the light loggers on outdoor fixtures. A significant number of false
positives were recorded on exterior fixtures during the day. At first,
we believed this could be avoided by using the logger's built-in sensitivity
adjustment to dull the photometric element so that it operated only when
the lights were on. However, the sun can be very bright--obviously brighter
than the researchers' anticipations! Fortunately, we were able to correct
our data--on days when the lights appeared to have gone off in the morning
and back on at midday, we were fairly sure that the sun was interfering
with the loggers. Another outdoor light logger became ineffective when
a dying moth, attracted to the fixture at night, fell onto the photosensor.
We recommend other sensing methods, such as clip-on
current transducers, for anyone attempting to monitor outdoor fixtures.
Transducers do not depend on light to show whether a fixture is on or not;
when it senses current passing through lamp wiring, it records that the
light is on.
 |
| Deck the halls with CFLs... |
The particular type of logger we used has a status
window to indicate whether the logger is sensing light. To set up the equipment
properly, one must be able to see this status window. However, once the
loggers are placed inside fixtures, status windows are often hidden. We
found that an inspection mirror helped us see around corners to make sure
sensitivity adjustments were correct.
We also learned about the danger of placing the
loggers too close to lamps. By accident, we melted one of the loggers in
the 180W incandescent kitchen drum fixture. Amazingly, the logger continued
to take useful measurements for the entire period. Even so, such circumstances
could create a fire hazard.
The Electric Bill That Stole Christmas
In our study, we found much higher lighting energy
use during December, thanks to the holidays. December had 27% more lighting
use than November. We wanted to know just how much energy those Christmas
lights use. Using a digital power analyzer, we measured the wattage of
five strings of commercially available Christmas lights. Each was classified
as a Decorative Lighting String by UL and was manufactured in China or
Thailand.
The electricity use of the bulb types varied
by a ratio of 46:1 between the highest and the lowest. In general, the
miniature incandescent W2 bulbs use only a fraction of the power of the
more traditional candelabra base bulbs. Since a typical Christmas tree
may have at least 100 bulbs, and the house may have twice as many outdoor
strings, connected decorative lighting loads could vary from a low of 60
W up to 3,000 W, depending on the types of holiday lighting system that
are chosen.
| Christmas Light Energy Consumption |
| Description |
No. of Bulbs |
Measured Watts |
Watts/Bulb |
| Small clear bulbs, indoor/outdoor, 36W |
100 |
34 |
0.34 |
| Small "midget globe bulbs," indoor, 10W |
50 |
11 |
0.22 |
| Small colored/clear bulbs, indoor/outdoor, 36W |
100 |
33 |
0.33 |
| C 71/2 5W bulbs, indoor/outdoor, 125W |
25 |
128 |
5.1 |
| Large 10W C bulbs, outdoor, 500W |
50 |
504 |
10 |
|
How Do You Like It?
Sometimes, to reduce wattage, we reduced effective
illuminance, with the approval of the homeowners. For instance, one occupant
thought the bare 60W incandescent globes on the master bathroom vanity
were too bright and asked for something with a softer light for the retrofit.
Based on the light logger data for this fixture, we knew that the vanity
lighting was not typically left on for long periods of time. Thus we substituted
conventional 40W incandescent globes to meet both objectives of reduced
wattage and lower light output. In other cases, the light output from the
newer fixtures actually increased; we communicated with the residents to
ensure that they were satisfied with the changes.
The occupants responded positively to most of
the changes. However, a CFL globe with a magnetic ballast was unacceptable
for the Florida room dining table due to its annoying start up flicker.
(This same lamp worked fine in the garage.) Similarly, the ten year old
boy who frequently uses the second bathroom was at first surprised by the
half second required for the electronically ballasted CFLs in the vanity
lighting to start up. The mother preferred the retrofitted kitchen task
lighting and saw no effective difference in the other fixtures. The father
noticed no real change in lighting quality, in spite of his stated preference
for a well-lit home (see "They Like It, They'll Pay, and
It Works").
The family was dissatisfied with the outdoor-lighting
motion sensors until they realized that they could override the controls
to keep the lights on. This proved to be a weak link in the overall retrofit.
The new front-porch lighting was higher wattage than before, and the motion
sensors were usually overridden during evening hours.
Similarly, the outdoor-lighting retrofit in the
rear included a porch light with a motion sensor that was frequently overridden.
The occupants left the light on from midnight until morning after the retrofit,
although they hadn't always left it on before. The motion sensor retrofit
saved little electricity except in the early evening hours.
Therefore, we recommend that retrofitters install
CFLs or other more efficient lighting in outdoor fixtures rather than depending
solely on motion sensor control. We could have obtained added savings of
nearly 1 kWh per day by substituting two 15W CFLs for the two 60W incandescents
lighting the front porch.
One place where motion sensors might have been
appropriate was the den, but we did not install them there. The father
frequently leaves table lamps on for many hours in the den with no one
in the room.
The Bottom Line
The new lamps and controls cost $405 retail. Paying
a retrofitter to do the changeover would have made the project far less
cost-effective, but we didn't include labor costs because the retrofit
is an easy
We estimated savings from the retrofit in two
ways. In the first method, we compared the metered lighting and plug loads
from June 20 to December 10, 1995 (before the retrofit) with the loads
from December 13, 1995 to June 20, 1996 (after the retrofit).
Figure 1. Average whole house lighting and miscellaneous
energy demand before and after the retrofit. The subtractive method of
determining savings assumes that the change is entirely caused by the lighting
retrofit. |
We found an average 6.8 kWh per day change over the period. Most savings
were in the hours between 7 am and midnight and were highest between 6
pm and 10 pm (see Figure 1). We witnessed a 40% reduction
in the metered lighting and plug loads, which we calculated to be a 61%
reduction in the pure lighting load. This works out to 2,500 kWh per year,
or about $200 at 8¢/kWh.
The second method we used for estimating energy
savings was more traditional. We knew the wattage change for each fixture
we retrofitted. We also knew the average daily use of each fixture, thanks
to the lighting loggers. We multiplied the wattage change by the hours
per day the fixture was on.
Unfortunately, the dead moth threw off the data
for the outdoor rear fixtures only two days after the light logger was
set up. As previously described, the motion sensor control of the front
porch lighting was largely overridden and few savings were observed there.
Thus, this method of estimating the savings did not account for any change
in the outdoor lighting from the retrofit. Light logger data was not available
for two altered fixtures due to a project oversight. Also, we logged most
of the fixtures during summer and early fall, missing the high-use period
in the middle of winter.
This method, therefore, gave us a very conservative
estimate of lighting energy use. Nevertheless, it showed a 47%, or 5.2
kWh per day, reduction in lighting energy use, amounting to 1,900 kWh per
year.
Depending on the estimation method, the simple
payback on this retrofit was between two and three years, for a simple
rate of return of about 40%.
What This Means to Everybody Else
Generally, in a residential retrofit, substitution
of CFLs for incandescent lamps is recommended for fixtures that are used
more than three hours per day. This recommendation is based on the relative
economics of installing CFLs against the produced rate of savings. For
instance, a 15W CFL substituted for a 60W incandescent lamp will produce
a savings of 49 kWh per year when burned for three hours a day. At 8¢/kWh
and a $15 lamp cost, the simple payback is 3.8 years, for an attractive
simple rate of return of 26%. At two hours per day burn time, the numbers
are still fairly attractive (5.7-year payback and an 18% rate of return).
However, when lamps are used for short periods of time, the economics rapidly
deteriorate. For instance, for a fixture used an average of only half an
hour per day, the payback time increases to 23 years and the rate of return
drops to 4%.
However, it can be difficult for auditors to
concentrate on heavily used lighting fixtures, since it's hard to know
which fixtures are used more than two hours per day. This article was adapted
from Danny Parker and Lynn Schrum, Results from a Comprehensive Lighting
Retrofit, FSEC-CR-914-96, available from the Florida Solar Energy Center,
1679 Clearlake Road, Cocoa, FL 32922-5703. Tel:(407)638-1000.In our study
the individual fixtures were metered, but most retrofitters will not have
the benefit of such information for the homes they deal with. Fortunately,
data from other studies provide insight into the typical hours that fixtures
are used in various rooms.
The usage in our house was similar to the typical
patterns found in the Tacoma study and other studies that preceded it.
All of these emphasize the need to address outdoor lighting energy consumption.
A simple rule of thumb, which our results bear out, is that all incandescent
lights outdoors, in kitchens, and in living rooms are good candidates for
replacement. Of course, circumstances differ in individual homes, and this
should only be used as a guide to provide a better match to actual needs.
We sought the maximum possible savings, so we
chose not to concentrate on high-use fixtures, but to install CFLs wherever
they could fit. Had we followed the above advice (changing lighting only
outdoors and in the kitchen and living room), we would have saved about
3.3 kWh per day, 30% of the household's lighting energy use, at a cost
of only $168 for 11 CFLs. This strategy would have missed lucrative opportunities
in the garage and den, but overall performance still would have been good--a
$96 annual savings and a 1.7-year payback.
Do the Savings Persist?
We examined the lighting retrofit six months after
installation. We found all but one of the lamps still in place, although
some table and floor lamps had been moved. One halogen bulb had broken
when a bedroom lamp fell. However, these changes probably won't change
the savings by much. A greater issue is long-term persistence. Even with
a 10,000 hour life, the most frequently used CFLs--and those providing
the best economics--will burn out and need replacement in two to four years.
We'll keep you posted. As for us, we're already off duplicating the above
research in two additional homes.
This article was adapted from Danny Parker and
Lynn Schrum, Results from a Comprehensive Lighting Retrofit, FSEC-CR-914-96,
available from the Florida Solar Energy Center, 1679 Clearlake Road, Cocoa,
FL 329922-5703.
Tel: (407)638-1000.
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