Module 1. Passive Design Strategies PDF

Summary

This document provides an overview of passive design strategies and architectural programming in architectural design. It covers various components, like identifying client needs, defining space requirements, and analyzing environmental factors. It discusses the importance of considering these factors for achieving energy efficiency and creating comfortable spaces.

Full Transcript

ARCHITECTURAL DESIGN 03

PASSIVE DESIGN STRATEGIES

WENDY VALERIE T. FERNANDEZ, UAP, RMP
AUGUST 24, 2024
ARCHITECTURAL PROGRAMMING
ARCHITECTURAL PROGRAMMING

Architectural programming establishes the needs and requirements
for all the functions in the building and their relationship to
one another.
ARCHITECTURAL PROGRAMMING

The amount of space needed and the relationship required among
the spaces are two primary factors in determining building size
and configuration.
ARCHITECTURAL PROGRAMMING

Key Components of Architectural Programming

1. Identifying Client and User Needs

2. Defining Space Requirements

3. Analyzing Environmental Factors

4. Establishing Functional Requirements

5. Budget Cost Considerations
ARCHITECTURAL PROGRAMMING

Key Components of Architectural Programming

6. Setting Design Goals and Aesthetic Considerations

7. Documenting the Program
ARCHITECTURAL PROGRAMMING

Wise programming maximizes energy savings by:

1. Placing spaces in the most advantageous position for day-
lighting

2. Thermal control

3. Solar integration
ARCHITECTURAL PROGRAMMING

Architectural programming involves an analysis of the required
spaces to meet the functional and operational needs of the
facility.

The individual spaces should be clearly described in terms of
their:
ARCHITECTURAL PROGRAMMING

1. Primary Function
2. Occupancy and Time of Use

3. Daylight Potential and Electric Light Requirements

4. Indoor Environmental Quality Standards

5. Equipment and Plug Loads

6. Acoustic Quality

7. Safety and Security
ARCHITECTURAL PROGRAMMING

8. Properly Sized Daylight Apertures

9. Utilizes Passive Solar Gain in Heating Mode

10.Minimizes Solar Gain in Cooling Mode

11.Facilitates Natural Ventilation

12.Good Solar Access for PV or Solar Thermal Systems

“ We shape our buildings, and afterwards our buildings shape us ”

- Winston S. Churchill, 1943
ARCHITECTURAL PROGRAMMING

Primary Function
ARCHITECTURAL PROGRAMMING

Primary Function

The core purpose of the space, such as whether it is intended
for office work, dining, sleeping, recreation, etc.
ARCHITECTURAL PROGRAMMING

Primary Function

Spaces with functions that require natural light should be
placed where daylight is abundant.

This reduces the need for electric lighting during the day,
enhancing energy efficiency.
ARCHITECTURAL PROGRAMMING

Primary Function

Example: A conference room’s primary function might be to host
meetings and collaborative work sessions.
ARCHITECTURAL PROGRAMMING

Occupancy and Time of Use

The expected number of occupants and the frequency and duration
of use.
ARCHITECTURAL PROGRAMMING

Occupancy and Time of Use

Example:

A cafeteria might be heavily occupied during meal times but
largely unused outside of those hours.
ARCHITECTURAL PROGRAMMING

Daylight Potential and Electric Light Requirements

The amount of natural light the space can access and the
supplemental electric lighting required to main-tain appropriate
light levels.
ARCHITECTURAL PROGRAMMING

Daylight Potential and Electric Light Requirements

Example:

An office space with large windows may rely on day-light during
the day but need adjustable electric lighting for early mornings
or late evenings.
ARCHITECTURAL PROGRAMMING

Indoor Environmental Quality Standards

Criteria such as air quality, temperature, humidity, and venti-
lation that need to be maintained for occu-pant comfort and
health.
ARCHITECTURAL PROGRAMMING

Indoor Environmental Quality Standards

Example:

A laboratory space might require strict temperature and humidity
controls to ensure the accuracy of experiments.
ARCHITECTURAL PROGRAMMING

Equipment and Plug Loads

The electrical load from all equipment and devices that will be
used in the space.
ARCHITECTURAL PROGRAMMING

Equipment and Plug Loads

Example:

A data center might have significant plug loads due to servers
and cooling systems.
ARCHITECTURAL PROGRAMMING

Acoustic Quality

The need for sound control, including the management of noise
levels, echoes, and acoustic privacy.
ARCHITECTURAL PROGRAMMING

Acoustic Quality

Example:

A library would require a design that minimizes noise to create
a quiet environment for reading and study.
ARCHITECTURAL PROGRAMMING

Acoustic Quality
ARCHITECTURAL PROGRAMMING

Safety and Security

The measures needed to protect occupants and assets, including
fire safety, access control, and emergency egress.
ARCHITECTURAL PROGRAMMING

Safety and Security

Example:

A hospital might need secure access to certain areas and clear
evacuation routes in case of an emergency.
ARCHITECTURAL PROGRAMMING

Safety and Security
ARCHITECTURAL PROGRAMMING

Properly Sized Daylight Apertures

The design of windows and other openings to allow sufficient
daylight without causing glare or discom-fort.
ARCHITECTURAL PROGRAMMING

Properly Sized Daylight Apertures

Example:

A classroom should have windows that provide ample daylight but
are equipped with blinds or shades to prevent glare on screens
or whiteboards.
ARCHITECTURAL PROGRAMMING

Properly Sized Daylight Apertures
ARCHITECTURAL PROGRAMMING

Utilizes Passive Solar Gain in Heating Mode

The design should maximize heat from the sun during colder
months to reduce heating demand.
ARCHITECTURAL PROGRAMMING

Utilizes Passive Solar Gain in Heating Mode

Example:

A living room in a residential building might be oriented to the
south with large windows to capture winter sunlight.
ARCHITECTURAL PROGRAMMING

Minimizes Solar Gain in Cooling Mode

Strategies to reduce unwanted heat from the sun during warmer
months through orientation, shading, and glazing choices.
ARCHITECTURAL PROGRAMMING

Minimizes Solar Gain in Cooling Mode

Example:

An office building might use external shading devices and low-e
glazing to minimize solar heat gain during summer.
ARCHITECTURAL PROGRAMMING

Facilitates Natural Ventilation

The ability of the space to allow fresh air to flow naturally,
reducing reliance on mechanical ventilation.
ARCHITECTURAL PROGRAMMING

Facilitates Natural Ventilation

Example:

A gymnasium might have operable windows or vents to enable
cross-ventilation and maintain air quality.
ARCHITECTURAL PROGRAMMING

Facilitates Natural Ventilation
ARCHITECTURAL PROGRAMMING

Good Solar Access for PV or Solar Thermal Systems

Ensuring that the space or building site has suffi-cient
exposure to sunlight for the effective use of solar energy
systems.
ARCHITECTURAL PROGRAMMING

Good Solar Access for PV or Solar Thermal Systems

Example:

A rooftop might be designed with unobstructed southern exposure
to optimize the efficiency of photovoltaic panels.
 IMPORTANCE OF
CLIMATOLOGICAL, ECOLOGICAL, SOLAR & WIND
CONSIDERATIONS, DAY LIGHTING
TO DESIGN
CLIMATOLOGICAL CONSIDERATIONS

Importance

Understanding the local climate is essential for de-signing
buildings that can withstand & take advantage of the prevailing
weather conditions.
CLIMATOLOGICAL CONSIDERATIONS

Importance

Climatological considerations help optimize the buil-ding's
thermal performance, reduce energy consumption, and enhance
occupant comfort.
CLIMATOLOGICAL CONSIDERATIONS

Example:

In a hot, arid climate, buildings can be designed with thick
walls, small windows, and shading devices to minimize heat gain
and keep interiors cool.
CLIMATOLOGICAL CONSIDERATIONS

Example:

In contrast, in colder climates, buildings can be designed to
maximize solar gain, using large windows on the south side to
capture and store heat from the sun.
CLIMATOLOGICAL CONSIDERATIONS

Example: Aït Benhaddou, Morocco
The buildings in Ait Benhaddou are mostly made of adobe, a
material that is readily available in the area.
CLIMATOLOGICAL CONSIDERATIONS

Example: Aït Benhaddou, Morocco
The walls of the buildings are thick and have small windows to
keep the interior cool during the hot summer months.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
The most prominent characteristics of this climate are the hot,
sticky conditions and the continual presence of humidity.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Air temperature remains moderately high.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Form and Planning

The building needs to allow maximum airflow and oriented to
catch and Increase whatever air available.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Form and Planning

The access to the rooms is usually from a veranda.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Form and Planning

Doors and window openings should allow maximum air movement,
hence large sizes are advisable.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Form and Planning

Elevate the building on stilts, consequently avoiding the
stagnant slow-moving air at the ground surface, capturing the
air movement of a higher velocity.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Form and Planning

Openness and shading will be a dominant feature of the building.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Form and Planning

Has to prioritize orienting the building to avoid solar heat
gain or increasing wind speed.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
External Spaces

Shading and path for air movement are the basic requirements to
achieve comfort.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
External Spaces

Vegetation is a reliable source for shading and adding value to
the outdoor space.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
External Spaces

Pergolas and light framing structure promote creepers growth,
thus provide shade.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Ventilation

Openings must be placed suitably following the prevailing
breeze to promote natural airflow, large and openable windows.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Ventilation

The airflow should not pass over hot surfaces like asphalt
before entering the building.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Ventilation

Without the exchange of air, both the temperature and humidity
of the air will increase due to heat and moisture from
occupants and their various actives like washing and cooking.
Frequent air change is essential.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Vernacular

The traditional shelter is often elevated on stilts and is
constructed from locally sourced timber or bamboo which is
open-weave matting, timber or split bamboo walls, floors, doors
and shutters.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Vernacular

The lightweight timber construction holds little heat and cools
adequately at the night.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Vernacular

The elevated position provides better security and better air
movement than a single storey shelter.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Vernacular

Thatch or built-up layers of leaves cover a bamboo or timber
roof-frame, which usually has broad overhanging eaves.
CLIMATOLOGICAL CONSIDERATIONS

HOT AND HUMID CLIMATE
Vernacular

The thatched roof is excellent thermal insulation. The broad
leaves shade the walls and openings, protect from the rain and
sky glare.
ECOLOGICAL CONSIDERATIONS

Importance

Ecological considerations ensure that the design mini-mizes its
environmental impact and enhances the natural surroundings.
ECOLOGICAL CONSIDERATIONS

Importance

This involves the responsible use of resources, minimizing
habitat disruption, and promoting biodiversity.
ECOLOGICAL CONSIDERATIONS

Example:

When designing a building in a forested area, eco-logical
considerations might include preserving existing trees, using
native landscaping to support local wildlife, and incorporating
green roofs or walls to provide additional habitats.
SOLAR CONSIDERATIONS

Importance

Solar considerations involve understanding the sun’s path and
its effects on the building throughout the year.
SOLAR CONSIDERATIONS

Importance

This is crucial for maximizing natural light, utili-zing passive
solar heating, and minimizing overheating.
SOLAR CONSIDERATIONS

Example

In a building designed for a temperate climate, solar consi-
derations might include large south-facing windows to capture
winter sunlight for heating, combined with shading devices to
block excessive summer sun and prevent overheating.
WIND CONSIDERATIONS

Importance

Wind considerations involve analyzing the local wind patterns to
optimize natural ventilation, enhance comfort, and reduce the
need for mechanical cooling. Wind can also be used to harness
energy through wind turbines.
WIND CONSIDERATIONS

Example:

In a coastal area with strong prevailing winds, buildings can be
oriented to take advantage of cross-ventilation, reducing the
need for air conditioning.
WIND CONSIDERATIONS

Example:

Windbreaks or strategically placed landscaping can also protect
outdoor spaces from harsh winds.
DAYLIGHTING CONSIDERATIONS

Importance

Daylighting involves designing spaces to maximize the use of
natural light, reducing the need for artificial lighting and
creating pleasant, well-lit environments.
DAYLIGHTING CONSIDERATIONS

Importance

Proper daylighting can enhance occupant well-being, productivity,
and energy efficiency.
DAYLIGHTING CONSIDERATIONS

Example

In an office building, daylighting considerations might include
the use of large windows, skylights, and light shelves to
distribute natural light evenly across workspaces.
DAYLIGHTING CONSIDERATIONS

Example

The design would also include controls for glare, such as
adjustable blinds or shading devices.
 SITING THE BUILDING
FOR SOLAR ACCESSIBILITY
SITING THE BUILDING

Careful site selection and building placement are essential for
optimal daylight and solar utilization.

1. Does the building site receive unobstructed solar radiation
between the hours of 9am to 5pm?
SITING THE BUILDING

Careful site selection and building placement are essential for
optimal daylight and solar utilization.

2. Are there major sky obstruction such as geological features,
trees, or adjacent buildings?
SITING THE BUILDING

Careful site selection and building placement are essential for
optimal daylight and solar utilization.

3. Does the site allow for an elongated east-west configuration?
BUILDING MASSING AND ORIENTATION
SITING THE BUILDING

Another energy-related massing and orientation consideration is
the seasonal wind pattern. Breezes can enhance natural
ventilation, but they can also increase heating loads in cold
weather.
SITING THE BUILDING

Effective daylighting depends on apertures of appropriate size
and orientation.

With interior and exterior shading devices to control unwanted
direct sunlight.
DESIGN OF HIGHPERFORMANCE FEATURES AND
SYSTEMS
FEATURES AND SYSTEMS

Uncontrolled solar gain results in high cooling loads, excessive
illumination, and glare.

The first strategy in passive cooling is solar heat gain avoi-
dance, which can be achieved primarily through shading and
glazing selection.
FEATURES AND SYSTEMS

Glazing selection is also an important consideration in window
design as it determines the visual, thermal, and optical perfor-
mance of the window.
FEATURES AND SYSTEMS

PASSIVE SOLAR DESIGN

Designed to maximize the use of natural systems to maintain
thermal comfort for the occupants.
FEATURES AND SYSTEMS

PASSIVE SOLAR DESIGN

A passive solar building successfully integrates the site, the
local climate and microclimate, the Sun, and local materials in
order to minimize dependence on external energy sources.
SOLAR SHADING
FEATURES AND SYSTEMS

SOLAR SHADING

Is the term used to identify a number of systems to control the
amount of heat and light admitted from the sun into a building.
FEATURES AND SYSTEMS

Solar radiation provides natural light and heat, which reduces
the need for artificial lighting and heating, although excessive
solar radiation could result in overheating, which would need to
be countered with cooling air conditioning.
FEATURES AND SYSTEMS

This is where solar shading methods can reduce the cost and
energy usage of this environment control. Another issue solar
shading alleviates is glare and other visual discomforts caused
to the occupants of the building.
FEATURES AND SYSTEMS

“Solar shading is important to mitigate the impact of a
building’s energy use whilst providing thermal and visual
comfort.”
SHADING STRATEGIES
FEATURES AND SYSTEMS

Well-designed sun control and shading devices, either as parts
of a building or separately placed from a building facade, can
dramatically reduce building peak heat gain and cooling
requirements and improve the natural lighting quality of
building interiors.
FEATURES AND SYSTEMS

Question:

What is more effective, the exterior or interior shading devices?
FEATURES AND SYSTEMS

Most effective solar shading devices are the exterior to the
building envelope.
FEATURES AND SYSTEMS

Intercepting sunlight before it reaches the walls and glazing of
a building dramatically reduces the amount of heat entering the
building.
FEATURES AND SYSTEMS

Shades and blinds located inside the building may be effective
at controlling glare, but are not effective in reducing the
solar entering the space.
FEATURES AND SYSTEMS

Exterior

Limit or protect the views of extremely bright exterior surfaces,
such as parked cars and large paving or sand areas.

The reflected glare from these surfaces can be visually
uncomfortable.
FEATURES AND SYSTEMS

Interior

Interior shading devices have limited solar control potential
and they often depend on user control to function properly. More
likely an occupant will set the shading device once and leave it
in position for the remainder of the day.
FEATURES AND SYSTEMS

Question:

Which type of solar shading should be used in north-facing,
south-facing, west-facing, and east-facing windows?
FEATURES AND SYSTEMS

Solar shading is most easily and effectively handled on south
and north elevations.
FEATURES AND SYSTEMS

SOUTH-FACING WINDOWS

Horizontal overhangs can adequately shade south-facing windows.
FEATURES AND SYSTEMS

NORTH-FACING WINDOWS

Receive predominately diffuse solar radiation and indirect day-
light, and therefore do not need more overhangs.
FEATURES AND SYSTEMS

EAST- AND WEST-FACING WINDWOWS

The most difficult to shade.

Early morning and late afternoon sun rays are approaching per-
pendicular to these windows, causing expressive heat gain and
visual glare.
FEATURES AND SYSTEMS

Minimize use of east- and west-facing windows.

When these windows cannot be avoided, carefully size and place
them for daylighting and view purposes only.
FEATURES AND SYSTEMS

Exterior Vertical Fins,

Overhang / Fin combinations,

Awnings,

Drop-down Shades

block the low morning and afternoon sun during warm periods.
FEATURES AND SYSTEMS

Incorporate mature trees on the east and west sides to cool
ground and air temperatures, intercepting sunlight before it
reaches exterior walls in summer.
FEATURES AND SYSTEMS

In hot climates that do not require heating, incorporate deep
porches, balconies and covered verandas to block east/west
sunlight all year and expand livable areas by creating shaded
comfortable outdoor spaces.
FEATURES AND SYSTEMS

Exterior drop-down shades and adjustable horizontal louvers or
blinds are also effective in blocking east-west sunlight.
FEATURES AND SYSTEMS
FEATURES AND SYSTEMS

Question:

Which color is ideal for solar shading devices?
FEATURES AND SYSTEMS

Consider light-colored surfaces on shading devices such as
overhangs, louvers, or light shelves.

Light-color shade to minimize heat gain.
FEATURES AND SYSTEMS

These light surfaces can help bounce diffuse sunlight into
building. Diffuse daylight is ideal for providing lighting
without glare.
FEATURES AND SYSTEMS

Light Shelf
FEATURES AND SYSTEMS

What is Light Shelf?

A light shelf is a passive architectural device used to reflect
natural daylight into a building.
FEATURES AND SYSTEMS

'Bouncing' sunlight off a horizontal surface distributes it more
evenly and deeply within a space, whereas direct sunlight can
cause glare near an opening, whilst leaving dark areas further
in.
FEATURES AND SYSTEMS

They are generally found on walls facing the sun, as on 'pole-
facing walls' would tend to act only as sunshades.
FEATURES AND SYSTEMS

On east and west orientations, they may act as an effective
means of reducing direct heat gain and glare but will not bounce
light as deeply into the space.
FEATURES AND SYSTEMS

To be able to reflect light up to the ceiling, the upper surface
of light shelves should be matte white or diffusely specular, it
does not need to be shiny or reflective. Ideally, the ceiling
should also be a light colour.
TYPES OF SOLAR SHADING
FEATURES AND SYSTEMS

Two Types of Solar Shading:

❏ Fixed

❏ Dynamic
FEATURES AND SYSTEMS

Fixed Solar Shading

This type of device is usually external and part of the
architectural design of the building, although fixed shading can
also be a separate structure or even trees and vegetation.
FEATURES AND SYSTEMS

Effective fixed solar shading depends on the orientation of a
buildings’ façade. It is necessary to understand the position of
the sun during the day in all seasons in terms of altitude and
azimuth angles.
FEATURES AND SYSTEMS

Types of Fixed Solar Shading
FEATURES AND SYSTEMS

Types of Fixed Solar Shading

❏ Overhangs, Vetical Fins or Balconies

❏ Canopies and Awnings

❏ Trees, Hedges and other Vegetation

❏ External Louvers or Brise-Soleil

❏ Recessed Windows

❏ Eggcrate Design

❏ Solar Control Glazing
FEATURES AND SYSTEMS

Overhang
FEATURES AND SYSTEMS

Overhang

The overhang or solar control, is used to keep the building’s
thermal mass in the shade. This will help keep the house cooler
in the summertime.
FEATURES AND SYSTEMS

Vertical Fins
FEATURES AND SYSTEMS

Vertical Fins

Extending outward from the exterior façade, vertical fins are
architectural elements that are both aesthetic and functional.

These vertical fins create a unique visual appeal while
providing solar shading and ventilation.
FEATURES AND SYSTEMS

Balcony
FEATURES AND SYSTEMS

Balcony

Balconies offer a similar opportunity to shade south facing
windows.

For top floor balcony windows, where there is no balcony above,
a canopy or brise soleil should be considered.
FEATURES AND SYSTEMS

Canopy
FEATURES AND SYSTEMS

Canopy

A canopy is an overhead structure typically intended to provide
shelter from rain or sun.

It is usually seen as a covering attached to the outside of a
building. It is also used for decorative purposes and to
emphasize a route or part of a building.
FEATURES AND SYSTEMS

Awning
FEATURES AND SYSTEMS

Awning

A sheet of canvas or other material stretched on a frame and
used to keep the sun or rain off a storefront, window, doorway,
or deck.
FEATURES AND SYSTEMS

Trees, Hedges and other Vegetation
FEATURES AND SYSTEMS

Trees, Hedges and other Vegetation

Solar heat absorbed through windows and roofs can increase
cooling costs. Incorporating shade from landscaping elements can
help reduce this solar heat gain.
FEATURES AND SYSTEMS

Trees, Hedges and other Vegetation

Trees shades reduce surface temperature, glare, and blocks the
diffuse radiation reflected from the sky and the surrounding
surfaces, thereby alerting the heat exchange between the
buildings and its sur-roundings.
FEATURES AND SYSTEMS

Trees, Hedges and other Vegetation

Shading and evapotranspiration (the process by which a plant
actively moves and releases water vapor) from trees can reduce
surrounding air temperatures.
FEATURES AND SYSTEMS

Trees, Hedges and other Vegetation

Deciduous Trees

Planting deciduous trees in front of windows that receive a
large amount of solar radiation can help to moderate the
temperature inside the home.
FEATURES AND SYSTEMS

Trees, Hedges and other Vegetation

Deciduous Trees

In the summer months when the tree has its leaves, the amount of
solar radiation into the home is limited. Conversely, in the
winter when the tree loses its leaves more Sun is allowed in and
the home is warmed.
FEATURES AND SYSTEMS

Deciduous Trees
FEATURES AND SYSTEMS

External Louvers or Brise-Soleil
FEATURES AND SYSTEMS

External Louvers or Brise-Soleil

Brise soleil is a type of solar shading system that uses a
series of horizontal or vertical blades to control the amount of
sunlight and solar heat that enters a building.
FEATURES AND SYSTEMS

External Louvers or Brise-Soleil

The name 'brise soleil' comes from the French word 'sun breaker'.
FEATURES AND SYSTEMS

Recessed Windows
FEATURES AND SYSTEMS

Recessed Windows

Orientation for passive cooling in hot and humid climate is
about blocking the sun as a source of free home heating by
reducing the direct solar radiation penetration through the
window. This strategy is done by setting the building’s
fenestration out of the direct rising and setting of the sun.
FEATURES AND SYSTEMS

Eggcrate Design
FEATURES AND SYSTEMS

Eggcrate Design

They are an economical way of creating a shading / sun-control
device that can be mounted to virtually any structure.
FEATURES AND SYSTEMS

Eggcrate Design

The best solution for hot-humid climate area where it combines
both horizontal and vertical shading devices.
FEATURES AND SYSTEMS

Solar Control Glazing

A solar control glass is a glass with a special coating designed
to reduce the amount of heat entering a building.
FEATURES AND SYSTEMS

Solar Control Glazing

It reflects and absorbs heat as well as filtering light for
reduced glare. Using a solar control glass can reduce the need
for air-conditioning and blinds.
FEATURES AND SYSTEMS

Solar Control Glazing

Select insulated Low-E Glazing units to reduce thermal loads and
provide better comfort in perimeter zones.
FEATURES AND SYSTEMS

Solar Control Glazing

Low-E Glazing

Low-E stands for "Low Emissivity". Low-E windows contain glass
that has been coated in invisible layers of metallic oxide.
FEATURES AND SYSTEMS

Solar Control Glazing

Low-E Glazing

This coating allows natural light to enter the home while def-
lecting UV rays and infrared light back out into the environment.
FEATURES AND SYSTEMS
FEATURES AND SYSTEMS

Low-E Glazing

Why is it important?
FEATURES AND SYSTEMS

Low-E Glazing

UV Rays

Are invisible rays of light emitted by the sun.
FEATURES AND SYSTEMS

Low-E Glazing

UV Rays

Are invisible rays of light emitted by the sun.

UV rays are responsible for fading upholstery, burning skin and,
over the course of many years, damaging building materials.
FEATURES AND SYSTEMS

Low-E Glazing

UV Rays

By deflecting both types of light back out into the environment,
low-E coatings help keep your home warm in winter and cool in
summer
FEATURES AND SYSTEMS

LOW-E Coating Benefits

1. Dramatic reduction in heat loss

2. Cost Savings

3. Invisible

4. Durable

5. Protection of furniture, flooring material, and upholstery.
FEATURES AND SYSTEMS

LOW-E Coating Types

1. Hard Coat

2. Soft Coat
FEATURES AND SYSTEMS

LOW-E Coating Types

Soft coat Low-E coatings have a higher R-value, so they provide
better insulation than hard coat.
FEATURES AND SYSTEMS

R-VALUE

The measurement of an insulation sheet's ability to resist heat

flow.
FEATURES AND SYSTEMS

The higher the number is, the more effective the insulation
sheet is at increasing thermal efficiency, and thereby,
insulating your home.
FEATURES AND SYSTEMS

Solar Control Glazing

SHGC Solar Heat Gain Coefficient

Ratio of total transmitted solar heat to incident solar energy.
FEATURES AND SYSTEMS

Solar Control Glazing

A value of 1.0 indicates the 100% of the solar gain enters the
building.

A value of 0.0 indicates no solar gain is entering the space.
FEATURES AND SYSTEMS

Solar Control Glazing

The lower the SHGC, the less solar heat it transmits and the
greater its shading ability.

A product with a high SHGC rating is more effective at
collecting solar heat during the winter.
FEATURES AND SYSTEMS

Solar Control Glazing

Low SHGC is desired on east and west facades ( less than 0.35 ).
FEATURES AND SYSTEMS

Solar Control Glazing

Windows shaded by overhangs on the south facade should have high
SHGC ( 0.70 or greater ).
FEATURES AND SYSTEMS

Solar Control Glazing

North-facing windows can typically have high SHGC values.
FEATURES AND SYSTEMS

Types of Dynamic Solar Shading
FEATURES AND SYSTEMS

Types of Dynamic Solar Shading

❏ Internal Blinds

❏ Curtains

❏ Internal Shutters

❏ External Shutters

❏ Adjustable Awnings, Louvers, and Canopies
TYPES OF SOLAR SHADING
Based on their Location in the Building
FEATURES AND SYSTEMS

Two Types of Solar Shading:

Based on their location in a building

1. Internal

2. External
FEATURES AND SYSTEMS

Internal Shading

Internal shading is less effective at reducing solar heat gain
than external shading because the solar radiation has already
come through the glass.
FEATURES AND SYSTEMS

Internal Shading

Usually are adjustable and allow occupants to regulate the
amount of direct light entering their space.
FEATURES AND SYSTEMS

Internal Shading can be a Useful Device when:

❏ The sun penetrates for only a short time

❏ Heat build-up will not be a major problem

❏ Windows can be left open adjacent to them

❏ It is required to reduce glare
FEATURES AND SYSTEMS

Internal Shading Options

❏ Curtains

❏ Venetian Blinds

❏ Roller Blinds

❏ Pleated Blinds

❏ Vertical Louvre Blinds

❏ Blackout Blinds
FEATURES AND SYSTEMS

Curtains
FEATURES AND SYSTEMS

Curtains

Curtains have been around for hundreds of years and a grand set
of curtains draped from a rail can add a luxurious finish to any
room.

Is the most commonly used shading device
FEATURES AND SYSTEMS

Benefits of Curtains

1. Mostly used on residential buildings.

2. Cheaper in comparison and can be found in various varieties,
colors, and texture.

3. Different thickness options.
FEATURES AND SYSTEMS

Disadvantages of Curtains

1. They reduce ventilation and block views.

2. Most not suitable for bathrooms / kitchens.

3. Can’t filter in light; must be either open or closed.
FEATURES AND SYSTEMS

Venetian Blinds
FEATURES AND SYSTEMS

Venetian Blinds

Venetian blinds are made from aluminium, real wood, or faux wood.
To keep things simple, we will call them aluminium blinds or
wooden blinds for short.
FEATURES AND SYSTEMS

Benefits of Venetian Blinds

1. Because of their slat control, they offer unmatched control
over light entering your room.

2. All slats in unison can be rotated through nearly 180 degrees.
FEATURES AND SYSTEMS

Disadvantages of Venetian Blinds

1. While these blinds bl o c k a l o t o f l i g h t , t h e y a r e n o t
blackout blinds. Even when the blinds are fully closed,
they’ll let low levels of light through each slat.
FEATURES AND SYSTEMS

Roller Blinds
FEATURES AND SYSTEMS

Roller Blinds

Roller blinds are a type of fabric blind that come in a choice
of one or two rollers.
FEATURES AND SYSTEMS

Benefits of Roller Blinds

1. Roller blinds are one of the most versatile choices for
blinds.

2. They can come in a variety of different fabrics, light fil-
tration, colours, and patterns. Perhaps the most versatile
fabric is PVC.

3. It is naturally flame retardant, waterproof, easy-to-wipe,
and sturdy – making it great in any room.
FEATURES AND SYSTEMS

Disadavantages of Roller Blinds

1. Reduce the light admitted but also reduce the heat gain by
only a small amount.

2. They may also reduce ventilation and block views.

3. Roller blinds are also a poor choice for energy efficiency.
To roll up seamlessly they are made from a very thin fabric.
FEATURES AND SYSTEMS

Roman Blinds
FEATURES AND SYSTEMS

Roman Blinds

Roman blinds are a luxurious choice for covering a window. Made
from a thicker fabric than roller blinds, they have rods sewn
inside to create even folds. As you pull the cord, these blinds
neatly unfold from the top of the window.
FEATURES AND SYSTEMS

Benefits of Roman Blind

1. Roman blinds are a great choice for during the winter when
you need blinds with thermal lining and a smart way to
introduce energy efficiency in your home.
FEATURES AND SYSTEMS

Disadvantages of Roman Blind

1. Roman blinds are never a good choice for damp environments
such as kitchens or bathrooms.

2. Their luxurious design comes at a premium cost.
FEATURES AND SYSTEMS

Pleated Blinds
FEATURES AND SYSTEMS

Pleated Blinds

Pleated blinds are made of lightweight fabric, stiffened with a
thin layer of glue, and folded to create an accordion effect.
FEATURES AND SYSTEMS

Benefits of Blinds

1. Pleated blinds use a tab to open and close the blinds instead
of a cord.

Cords present a potential hazard for young children, parti-
cularly in areas where they’re easily reached by curious hands.
FEATURES AND SYSTEMS

Disadvantages of Blinds

1. They offer a small amount of insulation, especially when
keeping heat out in summer.
FEATURES AND SYSTEMS

Vertical Blinds
FEATURES AND SYSTEMS

Vertical Blinds

Vertical blinds function a lot like venetian blinds in their
design. Instead of being horizontal, they’re vertical – but it’s
the same concept.
FEATURES AND SYSTEMS

Benefits of Vertical Blinds

1. Vertical blinds are perhaps the most affordable choice for
full-size windows and doors.

2. Suitable for many applications in commercial and public
buildings where the control of heat, light, and glare are of
concern.
FEATURES AND SYSTEMS

Disadvantages of Vertical Blinds

1. Vertical blinds are typically chosen to cover large areas, so
when it comes to cleaning them, you need to wipe each vane
separately.

2. Can be used to adjust the amount of incoming light while
retaining views but they reduce heat gain by only a small
amount.
DESIGNING SHADING SYSTEMS
FEATURES AND SYSTEMS

1. Use fixed overhangs on south-facing glass to control direct
beam solar radiation. Indirect (diffuse) radiation should be
controlled by other measures, such as low-e glazing.
FEATURES AND SYSTEMS

2. To the greatest extent possible, limit the amount of east and
west glass since it is harder to shade than south glass.
Consider the use of landscaping to shade east and west
exposures.
FEATURES AND SYSTEMS

3. Consider shading the roof even if there are no skylights
since the roof is a major source of transmitted solar gain
into the building.
FEATURES AND SYSTEMS

4. Remember that shading effects daylighting; consider both
simultaneously. For example, a light shelf bounces natural
light deeply into a room through high windows while shading
lower windows
FEATURES AND SYSTEMS

5. Do not expect interior shading devices such as Venetian
blinds or Vertical louvers to reduce cooling loads since the
solar gain has already been admitted into the work space.

However, these interior devices do offer glare control and
can contribute to visual acuity and visual comfort in the
work place.
FEATURES AND SYSTEMS

6. Study Sun Angles. An understanding of sun angles is critical
to various aspects of design including determining basic
building orientation, selecting shading devices, and placing
Building Integrated Photovoltaic (BIPV) panels or solar
collectors.
FEATURES AND SYSTEMS

7. Carefully consider the durability of shading devices. Over
time, operable shading devices can require a considerable
amount of maintenance and repair.
FEATURES AND SYSTEMS

8. When relying on landscape elements for shading, be sure to
consider the cost of landscape maintenance and upkeep on
life-cycle cost.
SOLAR SHADING CALCULATION
SOLAR SHADING CALCULATION
SOLAR SHADING CALCULATION

Solar Altitude Angle

Is the angular distance between the rays of Sun and the horizon
of the Earth.
SOLAR SHADING CALCULATION

Solar Azimuth Angle

Is the angular distance between the zero azimuth (either due
South or due North, and the projection of the line of sight to
the sun on the ground.

The azimuth angle is measured clockwise from the zero azimuth
SOLAR SHADING CALCULATION
SOLAR SHADING CALCULATION

Solar Incidence Angle

The solar incidence angle, θ, is the angle between the sun's rays
and the normal on a surface.
SOLAR SHADING CALCULATION
SOLAR SHADING CALCULATION
SOLAR SHADING CALCULATION

Wall Azimuth Angle

A building's exterior wall azimuth (also referred to as exposure
orientation) is the direction faced by the wall.
SOLAR SHADING CALCULATION

Wall Azimuth Angle

A building's exterior wall azimuth (also referred to as exposure
orientation) is the direction faced by the wall.

It is the direction that you are looking at when looking out
through the window in the wall from inside the building.
SOLAR SHADING CALCULATION
THANK YOU & GOD BLESS!