Sustainable outdoor lighting:
the most efficient and least polluting
Outdoor lighting reconstruction is an excellent possibility to achieve
a~much better service with much less power consumption. This is
important, as the power consumption for streetlighting rises steadily
(by some 1 per cent per year in the EU), with light amounts (and,
consequently, pollution of night environment by light, as pollution =
change of the particular parameter of the environment due to added
components of anthropogenic origin) rising twice more quickly, due to
improved lamp and luminaire efficiencies. The development of outdoor
lighting up to now has been completely unsustainable.
Unfortunately, such achievements (better service with less light and
power) are extremely scarce outside those six Italian regions where
effective environmental legislation concerning outdoor lighting exists.
Such a~legislation was introduced in Lombardy in 2000 (by unanimous
vote of all representatives) and made even more demanding in 2004
(protecting all nature protected areas against man-made light, see e.g.
http://cielobuio.org). Its
success led to its replication in five another regions, including all
Adriatic coast. The principles contained in that legislation are as
follows:
- no light emissions horizontally and upwards (technically, it's
expressed as 0~cd/klm)
- no more light onto the target area than recommended by safety
standards
- just the most efficient lamps allowed
- optimised pole positions and light proportion hitting
the proper target
- dimming technology applied (allowing to reduce the light flux by
at least thirty per cent)
The same principles are to be obeyed everywhere, for any new lighting
installation or a~reconstruction, to achieve its best quality and low
power consumption. They should be demanded for each project, which is not
financed altogether by private money of its owner -- the donors can
make these principles obligatory (such an approach, using a~less
comprehensive set of principles, is applied e.g. by the US state
Connecticut).
Comments on single points
Ad 1, no light emissions horizontally and upwards (0~cd/klm in these
directions)
Usually, just luminaires with no lens which would protrude down
from the upper opaque luminaire body, can fulfil the requirement. Flat
glass, hidden in the luminaire body, is mostly used as their lens
(protecting the luminaire optics from dirt and insects) -- this can be
made from non-absorbing glass (low-iron one, common for solar
collectors) covered with ideal, durable anti-reflective layers (with
a~third-millennium technology of sol-gel dip process and subsequent
hardening; such glass is becoming common e.g. for protecting most
valuable paintings, as it is almost invisible), to achieve
maximum efficiency.
Such luminaires have to be installed perfectly
levelled (when tilted, even an excellent luminaire shines far away into improper
directions). If old poles with tilted arms are used, the luminaires
have to contain a~joist to compensate the tilt,
or there is to be an adapter
with such a~joist or bend between the arm and the luminaire.
(What's 0~cd/klm? Less than 0.500~cd/klm. For a~good 50W high-pressure
sodium lamp producing 4400 lumens = 4.4~klm, this means that the
luminous intensity of the installed luminaire, to any horizontal or
upward direction, can be anything below 2.20~cd. In another words, it
can be as bright as two candles together.)
Ad 2, no more light onto the target area than recommended by safety
standards
This deserves to be extended. Adhering to any outdoor lighting standards is
voluntary. So it is, which standards will be chosen.
There are standards on street illumination
meant for hurrying car drivers (riding at speeds over 50~km/h) to help
them to see where the road goes or to notice minor obstacles on the road
-- these recommend some minimal luminance (how bright the road appears)
in large distances, over 60~m from the driver. And there are standards
serving primarily to pedestrians and cyclists, to see well and to be
seen by drivers -- these should be applied within town and village
streets. These standards speak about average illuminances of the streets
(in lux) and their uniformities (ratios of minimum to average
illuminance) or explicitly about illuminances of the least lit spots.
This last quantity is the important one: it says, what amount of light
is enough for adequate visibility. When this is enough, there is no
reason to have more elsewhere: the average values should be, ideally,
very close to these minima. Any brighter, more intensively lit spots are
a~hindrance to see well the minimally lit areas. And any directly
visible lamp or a~luminous opening of a~luminaire is a~hindrance too,
perceived as glare.
A~municipality can choose to which light levels it
wants to light the streets. A higher level of illuminance means,
inevitably, increase of power consumption, with little benefit for
people (the eyes adapt to the prevailing light levels, not perceiving
their absolute values, and see well provided the glare is minimised). An
example of such three minimal illuminances (of ``darkest spots'') is
0.6~lx, 1~lx and 3~lx, depending on the maximum traffic on the street.
So, the 2nd rule should read rather: Choose the desired illuminances
(expressed in lux) of the least lit spots of each street, depending
on the maximum traffic on it. Try to keep the average value of street
illuminance less then twice the minimum value. Try to limit the maximum
spot illuminance; the higher it is, the darker the least lit spots
appear (remember that the best lighting is daylight, with its
completely uniform illuminance outside
shadows). For a~reconstruction,
don't increase light levels from the existing ones without a~serious
reason, instead, try to make the illumination more uniform. Check if
the past light levels were not too high (maybe, due to a~wish
to compensate dark spots which people didn't like). Consider, that
a~common full-moon light is about 0.1~lx and even the strongest winter
full moon high in the sky does not illuminate the landscape by more than
1/4~lx.
Increasing light levels a~lot by the reconstruction would be unsustainable,
even if power consumption would be reduced and quality of lighting
improved (less glare and better uniformity). It would give a~false
signal to another municipalities: let's add light too!
The reconstruction should boost the quality, not the quantity of
light.
Not more light, but a~lower speed limit (and its monitoring and
enforcement) is the really helpful measure to increase safety. It might
be wise to impose a~special local speed limit at night, if the default
nationwide limit is too generous. The risk of accidents is larger at
night than in daytime, regardless of artificial light intensities
(e.g., due to fatigue of drivers), and also noise is more harmful at
night (lower speed reduces noise a~lot). 40~km/h would be a~reasonable
compromise with hurrying drivers even in those streets where 60~km/h
applies in daytime. Lower speed reduces fossil carbon emissions, whereas
more artificial lighting increases them.
Ad 3, just the most efficient lamps allowed (emitting 87~lm/W or more,
if 50W or stronger lamps are employed)
The most efficient strong light sources are low pressure sodium lamps,
then high pressure sodium lamps.
Fluorescent lamps may be the best solution
for cases where more efficient lamps are too strong (the
goal is the minimum power consumption, for the chosen minimum
levels of illumination).
For low luminous fluxes, LEDs are
becoming to be able to offer the needed illuminance with less power
(thanks to excellent possibilities to direct their light just where
needed).
The point was meant to exclude the use
of mercury
vapour lamps and low-efficiency versions of sodium lamps.
This is to be extended by including power consumption of the
so-called ballasts, which limit the current to the discharge lamps. The
power consumption of lamps+ballasts (usually 1.1× to 1.3× the
consumption of lamps themselves) is to be minimised. Electronic
ballasts are to be preferred, as they convert less power to heat.
And, in fact, the ``lumens per
watt'' should be considered not for a~new lamp, but rather for a~lamp
after some 12000 hours of duty (four years of all-night use) -- this
applies primarily to metal halide lamps, whose luminous output
decreases a~lot during their lifetime.
Ad 4, optimised pole positions and light proportion hitting
the proper target
The point might read: find the minimum possible light emissions from the
luminaires, which provide the desired minimal illuminances of the street
(of course, this implies minimising any light going away from the street
pavement, and avoiding any illuminances larger than the desired minimal
one at the pavement). The requirement regarding poles concerns
investment costs if new poles are installed: their number should be
kept low, as each additional pole is expensive (even the maintenance
costs rise). The Italian regional environmental
legislation demands pole distances being at
least 3.7× their height. The better the light distribution from the
luminaires (as little light outside the street as possible, large
luminous intensities directed into the middle between the poles,
and less light steep down to avoid a~bright spot
below each luminaire), the less number of poles is needed and the less power is
needed for the specified lighting task.
In fact, the goals 2, 3 and 4 are to be solved together, using such
luminaires which offer the least power consumption for achieving the desired
minima of luminance in the least illuminated spots. It can happen, that
the most efficient solution misses the desired light levels just a~bit
(e.g., using 35W lamps, whereas the next available ``size'', 50~W would
give almost twice more light then needed). Then the fainter-lamp
solution is the proper one: reducing the light levels by thirty per cent
is irrelevant, nobody can notice the difference. Twice less light
becomes apparent if the nominal intensity and the halved one are put
side by side, so that the eyes can compare them instantly.
Ad 5, dimming technology applied (allowing to reduce the light flux by
at least thirty per cent)
Technically, all lamps (but low-pressure sodium ones) can be dimmed not
BY one third, but even TO one third, of their nominal luminous flux.
This is the desired level later in the evening, when the traffic calms
down. As it concerns most of the night (e.g., it can be applied
gradually since 7 or 8 p.m. in winter, and for the whole night in
summer), it enables huge power savings. At the same time, thanks to
stabilisation of voltage early in winter evenings when the lamps work at
their nominal output, lamp lives are prolonged, sometimes more than
twice. This saves both maintenance labour costs and environment (less
lamps need be produced, purchased and recycled).
Two technologies are competing here: central dimming by reducing the
voltage by which the lighting system is fed (this assumes using just
low-efficiency magnetic ballasts in the luminaires) and individual
dimming by using hi-tech electronic ballasts in the luminaires. Such
ballasts can offer either two light levels or a~continuous dimming to
any light level. The latter one should be able to keep the lamp flux on
the desired level all the lamp life (the lamp is more efficient when
new, and sometimes its nominal output, due to the discrete offer of lamp
wattages, is a~bit too large even after years of duty). Electronic
ballasts may be programmed manually, or digitally controlled by
impulses sent through the power grid or by wireless technologies.
Last but not least, even if lighting can be dimmed to one half or one
third for most of the night, the environment-friendly option is to
switch it altogether, when not needed by anybody. Light does not
protect us from ghosts or criminals, this is but a~deeply rooted
superstition. Years of lamp lives are increased exactly proportionally
to the length of switch-off night intervals, and of course power is
saved too, so simply.... Car drivers find their way even with no
streetlighting, and people sleep better in unlit streets. Natural
darkness is healthy for us and the wildlife. There are many villages and
towns across Europe which switch off their lights for long parts of
nights (not switching them on at all at the end of the night from May to
July, as there is daylight already when people get up, also thanks to
the daylight-saving time). Avoiding strong light indoors late at night
(what is reasonable also for human metabolism and health, even when
people don't sleep) enables people to adapt to natural light levels
outdoors to see their way (except perhaps within deep forests), as was
the case all the times since homo sapiens appeared.
Further information
A~European conference on outdoor lighting takes place at lake Bled,
Slovenia, in October. See http://www.darksky2007.si and study the outstanding
conference brochure, even if you cannot participate at the conference.
For a~draft introduction to the environmental aspects of lighting see
http://amper.ped.muni.cz/light/EuP/lp_intro.htm,
this gives links to some documents on
pollution measurement,
legislation,
luminaire parameters and
technology.
A~comprehensive gate to the topics is http://savethenight.eu
Jan Hollan, May 2007