Climatic Design PDF

Summary

This document discusses various aspects of climatic design, focusing on shading techniques and strategies for building design. It covers topics such as solar radiation control, understanding shading, and differentiated facade treatments.

Full Transcript

ARCH 400 | CLIMATIC DESIGN
ARCH. JIFFER JOHN L. TAALA, UAP, PSPE, MSSD
SHADING – HEAT AVOIDANCE
UNDERSTANDING SHADING
"The easiest way to reduce the energy required to
cool a building is to avoid heat gain"
CONTROL OF SOLAR RADIATION THROUGH SHADING:
In order to control sun penetration to the interior of
buildings it is important to provide exterior
shading as a part of the architectural envelope
design. Such shading devices can be attached to the
building or can be achieved by the articulation and
disposition of the building floors to create
overhangs.

Sources of Solar Radiation that May Require Shading

https://www.tboake.com/carbon-aia/strategies1b.html
Exterior shading is greatly preferred over interior shading as it is
important to keep the solar radiation/heat from entering the
building. Traditional interior blinds or drapes merely block the
glare of the sun, but still allow the heat to enter the interior
space.

Incidence Angle Shading:
At high angles of incidence, where the sun's rays are almost
parallel to the window surface (at glazing angles), glass becomes
more reflective. At incidence angles of 80o, both single and double
pane glazings (clear plate glass) become about 50%
reflective. This geometry occurs when profile angles are very
high, window azimuth angles are high, or both. This will reduce
solar radiation transmitted through the glass by an equal
percentage. Some other problems like interior glare or reflected
glare from the facade to the exterior may occur.
Air Mass Shading:
As a function of solar altitude, the air mass extinction becomes
critical at about air mass 5.0. This relates to a solar altitude of 12
degrees above the horizon or less. At these low altitudes, the sun
is more of a glare problem than heat gain. This notion works
against a building which tries to collect low winter sun. Shading
devices should allow for the fact that incidence and air mass
shading will eliminate some periods of the year from
consideration but may still require shielding from glare.
Diffuse Solar Energy:
Shading devices are usually configured to provide agains direct
beam sunlight and from the brightest part of the sky on cloudy
days. Some scattered (diffuse) energy will still arrive at the
window. For a fully shaded window, we usually consider the
incident solar energy to still equal that of a expose window on a
shaded north elevation. The actual insolation received for a fully
shaded window is a function of how much sky the window 'sees'
and how reflective the foreground landscape is.
Benefits/Detriments of Shading Locations and Types
DIFFERENTIATED FACADE TREATMENT:
An understanding of solar geometry tells us that the
exposure of each facade to the sun is different, and
varies by orientation. Each orientation of the building
requires a different approach to the design of
shading. The north elevation (in the northern
hemisphere) essentially does not require shading
because except in the summer months in the early
morning and late evening, no sun penetration occurs. At
this time of day the sun angle is so low that horizontal
projections would be useless as shading devices. It is
best to limit as much as possible fenestration on the
north elevation as there will be very little solar heat gain
and much direct heat loss from this side. If fenestration
is required for daylighting, then it is important to select
a highly efficient glazing assembly to reduce energy
transfer.

The south elevation (in the northern hemisphere) allows
for the easiest control of solar energy. Shading devices
are normally designed as horizontal projections above
the windows -- the length of the projection is
determined as a geometric function of the height of the
window and the angle of elevation of the sun at solar
noon. Such shading devices can be designed to
completely eliminate sun penetration in the summer and
allow for complete sun penetration during the winter
when such is desired for passive heat gain.

Basic Shading Strategy for a South Elevation
The east and west elevations are both difficult to shade
“architecturally”. The sun angles in the morning and afternoon are
low enough to preclude shading using overhangs. The morning
sun is normally cooler and less offensive than the heat and glare
of the late afternoon sun.

Shading needs to be provided in the way of landscaping and
foliage. Deciduous trees are effective as they block the sun in the
summer when it is not desired and allow sun penetration during
the winter. Fences work to block the sun and view at all times of
the year and so are not so climatically responsive. Vines on more
transparent “fence like” elements are effective as they too bear
leaves to shade in the summer, and keep their leaves until later in
the fall when sun is again desired. Vines are often used as well on
south facing elevations on trellises to achieve seasonal variation
in the opaqueness of the overhangs. Shading Issues with East and West Facades

The natural environment can be used to shade low rise buildings.
Deciduous trees can effectively shade the facade when heat
avoidance is desired, and permit solar penetration where passive
solar gain is sought. Vines can be used on trellises or trellis like
shading devices to the same effect. Vegetative shading also works
well with the shoulder heating and cooling seasons. In the spring
when heating is still often desirable, leaves are not yet present,
allowing continued passive heating. In the fall, when continued
warm days might suggest cooling, the leaves have not yet been
shed. If natural ventilation is also desired, it is important to allow
adequate wind penetration around exterior plantings or potential
natural cooling will be blocked.

Vegetative Shading
How Long to Shade For?
Shading devices for heat avoidance need to be designed
to be effective beyond the geometry of summer solstice
when the sun is highest in the sky. Depending on the
local climate conditions, cooling may be a priority from
the mid spring to early fall seasons. The length of the
south facing shading device should be sized for this
extended season.
The diagram above divides the types of shading devices
into fixed and movable. Movable shading devices may
include awnings, hinged extensions and vegetation. If a
mechanically dependent solution, the device needs to be
designed for durability.

The Shading Season
GENERAL TYPES OF
SHADING DEVICES:
The basic types of exterior shading devices can be identified
as HORIZONTAL, VERTICAL OR EGGCRATE. When designing
shading devices for heat avoidance it will be important to
also weigh the amount of solar penetration that is desired
during the heating months. Where the heating degree days Basic Typology of Horizontal Shading Devices for Southern Exposures
greatly exceed the cooling degree days (in COLD climates),
be careful not to compromise the potential for solar gain in
the winter months. Where the cooling degree days exceed
the heating degree days (HOT climates), shading should be
effective for a longer period. In some climates this may
warrant the virtual elimination of south facing windows, with
deference to north facing windows to promote daylighting.
Horizontal shading devices are suited to southern exposures.
Roof overhangs can also easily be used to shade southern
exposures on low rise buildings. This is perhaps the most
economical and potentially aesthetically pleasing solution for
residential applications.
Where sun is hitting the facade from a south-easterly or
south-westerly direction, vertical devices can effectively
block the sun. Eggcrates are often used on non true south
facing elevations as well.
Shading Devices for Non Southern Exposures
The general configuration of the
building can also be modified to alter
the orientation of windows for heat
avoidance.
For reasons of both heat avoidance and economy, it
is often best to "gang" the south facing shading
devices. In order to obtain shading in the late
morning and early afternoon when the sun is not at
its high point, the shading device should be extended
either side of the window opening.

Elevation of Shading Device Configurations for South Facing Facades Various Planimetric Configurations of Non South Facing Shading Devices
Daylight Zones:
Sidelighted Spaces
When designing an energy-saving daylight harvesting control
system, a critical decision is to establish lighting control zones,
identifying lighting loads to be separately controlled. Before this
decision can be made, however, we must first determine
the daylight zones.
A daylight zone, also called the daylight area (expressed in square
feet), is defined by the ASHRAE/IES 90.1-2010 energy standard as
“the floor area substantially illuminated by daylight.” In other
words, it should consistently receive significant quantities of
daylight during the day.
By identifying daylight zones, the lighting control system designer
identifies areas where daylight harvesting control is appropriate.
The designer can then make further decisions about how many
control zones are appropriate for the given daylight zone, and
their configuration.
http://lightingcontrolsassociation.org/2011/10/12/daylight-zones-
sidelighted-spaces/
https://www.usgbc.org/credits/new-construction-core-and-shell/v3-
leed-india-2011/eqc81
http://www.plea-arch.org/wp-content/uploads/PLEA-Note-4-
Daylighting-lowre.pdf
https://www.lightcloud.com/system/code-compliance/
https://www.wbdg.org/resources/daylighting
https://www.architectmagazine.com/technology/lighting/mastering-
sidelight_o
Skylit
Light shelf

https://www.sciencedirect.com/science/article/abs/pii/S0360132321008775
https://www.mdpi.com/1996-1073/12/22/4295/htm
https://www.researchgate.net/figure/Concept-of-a-variable-light-
shelf_fig1_324157317